Melomys cervinipes ( Gould, 1852 )

Melomys cervinipes ( Gould, 1852) View in CoL

Fawn-footed Mosaic-tailed Rat

Mus cervinipes Gould, 1852 :Plate 14; unnumbered page associated with plate. Type locality “Stradbrook Island,” Moreton Bay, Queensland, Australia.

Rattus leucosternum cervinipes: Fitzinger, 1867:68 . Name combination.

Uromys cervinipes: Thomas, 1888:237 . Name combination.

Uromys banfieldi De Vis, 1907:8 View in CoL . Type locality “Dunk Island, an island lying a little to the north of Cardwell, in lat. 15, long. 145,” South Mission, Queensland, Australia.

Melomys cervinipes: Thomas, 1922:261 View in CoL . First use of current name combination.

Melomys cervinipes eboreus: Thomas, 1924:297 View in CoL . Type locality “Dinner Creek, Ravenshoe. 2900’,” Mount Hypipamee National Park, Queensland, Australia.

Melomys cervinipes pallidus Troughton and Le Souef, 1929:98 View in CoL . Type locality “Hinchinbrook Island, near Cardwell, Queensland,” Australia.

Melomys cervinipes cervinipes: Iredale and Troughton, 1934:86 View in CoL . Name combination.

Melomys banfieldi: Iredale and Troughton, 1934:86 View in CoL . Name combination.

Melomys limicauda Troughton, 1935:255 View in CoL . Type locality “Hayman Island in the Whitsunday Group, on the north Queensland coast between Bowen and Mackay,” Australia.

Melomys cervinipes banfieldi: Rümmler, 1936:252 . Name combination.

Melomys cervinipes limicauda: Tate, 1951:292 View in CoL . Name combination.

Melomys cervinipes bunya Tate, 1951:293 View in CoL . Type locality “Bunya Mountains, 3500 feet,” Queensland, Australia.

CONTEXT AND CONTENT. Order Rodentia , family Muridae , subfamily Murinae , tribe Uromyini . The genus Melomys contains 21 species, of which 18 are native to New Guinea, Indonesia, and the Solomon Islands ( Menzies 1996; Wilson and Reader 2005) and 3 are native to Australia: grassland melomys Melomys burtoni, Cape York melomys Melomys capensis , and M. cervinipes (van Dyck and Strahan 2008; Jackson and Groves 2015). A 4th Australian species, Bramble Cay melomys Melomys rubicola , was declared extinct in June 2014 ( Woinarski et al. 2014). No subspecies are recognized within M. cervinipes .

NOMENCLATURAL NOTES. The original female Melomys cervinipes collected by Gould (1852) is the designated lectotype BM 52.12.15.1 ( Thomas 1921). Thomas (1888, 1902) and Thomson (1889) first mention Uromys cervinipes in their publications; however, the designation of the species cervinipes to the genus Uromys was only formally described by Ogilby (1892). Tate (1951) identified 9 subspecies (races) within M. cervinipes , 2 of which were elevated to full species rank ( M. capensis and M. rubicola ) and M. c. albiventer was synonymized within the sister taxon M. burtoni . All other races were synonymized within cervinipes by Watts and Aslin (1981) and Mahoney and Richardson (1988).

The generic name, Melomys is derived from the English Melanesia , indicating the wide distribution of species from this genus ( Thomas 1922), and the Greek mys for mouse ( Borror 1960). The species name cervinipes is from the Latin cerv for deer or fawn and pes for foot ( Borror 1960), referring to the light coloring (fawn) of the feet. Other vernacular names include bufffooted rat ( Gould 1852), (fawn-footed) mosaic-tailed rat (Taylor and Horner 1970), (fawn-footed) naked-tailed rat ( McKenzie et al. 1976), large khaki rat ( Redhead 1983), fawn-footed scaletailed rat ( Redhead 1983), tawny-foot Melanesian mouse (Moore and Burnett 2008), fawn-footed melomys ( Roberts 1963), and looloong (Aboriginal name—Braithwaite et al. 1995).

DIAGNOSIS

Melomys cervinipes ( Fig. 1 View Fig ) is so morphologically similar to its congener M. burtoni that field identification is often difficult. Although the 2 species occupy different habitats, there appears to be some overlap (van Dyck and Strahan 2008), making accurate field identification essential. Dyer (2007) found that absolute tail length and body mass, based on age class, could be simple field measures. However, how the age classes of animals were identified in the field was not given, and the tail ranges were very small considering the high sample numbers (e.g., length ranging just ± 0.5 mm from the species mean for mature male M. burtoni ). This is questionable, considering that tail length and body mass have been found to show considerable overlap in prior studies ( Keith 1970; Watts and Aslin 1981; Moore and Burnett 2008); thus, it is suggested that these are unlikely to be useful field identification measures. Keith (1970) found that tail length, as expressed as a percentage of head and body length, was longer for M. cervinipes by approximately 7%. However, this requires further validation, as the sample size for M. burtoni was small (n = 7). The number of tail scale rows differs between species, with M. cervinipes having 13 and M. burtoni having 14–15 ( Keith 1970). Frost (2008) and van Dyck et al. (2013) have developed a method of field identification using the length of the 1st and 5th interdigital pads, whereby individuals with a 1st interdigital pad greater than 2.3 mm and a 5th interdigital pad greater than 1.7 mm can be classified as M. cervinipes . The 2 species can also be distinguished by their dentition ( Keith 1970; Knox 1978), although this is not useful for identification in the field. The toothrows of M. cervinipes show a greater angle of divergence, and the length of the toothrow is longer relative to the difference in the distance across the mouth between M 1–1 and M 3–3 ( Keith 1970). The upper molar alveolar patterns are also distinct, with M. cervinipes showing 4 roots on the 1st and 2nd upper molars, whereas M. burtoni has 5 ( Knox 1978). M1 alveolar length is also a distinctive character (93.5% effectiveness of species determination), with a value greater than 3.1 mm characteristic of M. cervinipes ( Knox 1978) . M. cervinipes shows a broader interorbital region than M. capensis , which is posteriorly undercut at the sides of the orbits, and with more pronounced ridges on the upper surface (Watts and Aslin 1981). In addition, the anterior palatal foramina broadens posteriorly and the molars are larger (Watts and Aslin 1981).

Melomys cervinipes can also be differentiated from M. capen - sis and M. rubicola based on geographic range. M. capensis is found on the Cape York Peninsula and M. rubicola is found on Bramble Cay Island (van Dyck and Strahan 2008).

GENERAL CHARACTERS

Melomys cervinipes is a small, light gray-brown to russet brown (color is highly variable and can change with age—Watts and Aslin 1981) murid rodent with a white to cream ventral surface, a brown to black tail, and light fawn-colored feet (Moore and Burnett 2008). Young animals are often a uniform light gray (Watts and Aslin 1981). The fur is soft, fine, and long, and dark whiskers are conspicuous on the muzzle (Watts and Aslin 1981). There is no apparent sexual dimorphism in color. The ears are short, rounded, and dark gray to black, and the eyes bulge conspicuously (Watts and Aslin 1981). As for all members of the tribe Uromyini , the tail is naked, with the scales arranged in a mosaic-like pattern (interlocking with little overlap—Watts and Aslin 1981), with short hairs ( Harrison 1962; Breed and Ford 2007), and is approximately equal to the head–body length (Watts and Aslin 1981). The tail is partially prehensile, with the tip capable of curving round objects to potentially provide support ( Harrison 1962). The hind feet are long and wide. Mean measurements (value ± SD; with parenthetical ranges when appropriate—compiled from Harrison 1962; Keith 1970; Taylor and Horner 1970; Wood 1971; Watts and Aslin 1981; Leung 1999; Moore and Burnett 2008) of M. cervinipes (sexes combined) were: body mass, 72.9 ± 12 g (37–120 g); head–body length, 133.5 ± 12.7 mm (100–197 mm); tail length, 142.6 ± 10.9 mm (105–180 mm); hind foot length, 27.5 ± 0.8 mm (25–29.2 mm); ear length, 18.3 ± 1.6 mm (14–20.9 mm).

The head is broad (Watts and Aslin 1981) and the skull delicate ( Fig. 2 View Fig ). The skull is difficult to distinguish from that of M. burtoni , although there is a tendency toward larger size, with divergence in the posterior molar rows, compared to the more parallel rows of M. burtoni ( Keith 1970) . Mean ± SD craniodental measurements (mm; with parenthetical range—compiled from Harrison 1962; Keith 1970; Watts and Aslin 1981; Bryant 2013; TLR) of adult M. cervinipes (sexes combined) were: greatest skull length, 33 ± 1.7 (26.4–39.5); condylobasal length, 31.2 ± 1.6 (28.9–33.4); basal length, 28.8 ± 1.7 (26.5–31.1); zygomatic breadth, 17.4 ± 0.9 (13.7–20.7); interorbital width, 5.3 ± 0.1 (3.8–6.6); interparietal length, 9.9 ± 0.2 (9.5–10.1); interparietal width, 4.6 ± 0.2 (4.3–4.8); braincase width, 15.3 ± 0.2 (15–15.6); rostrum length, 10.9 ± 0.7 (7.1–11.6); rostrum width, 3.6 ± 0.2 (3.3–3.9); maximum rostrum width, 6.4 ± 0.1 (4.8–7.6); palatal length, 17.2 ± 0.8 (16.2–18.3); length of the anterior palatal foramina, 5.8 ± 0.4 (4.9–7.9); width of anterior palatal foramina, 2.3 ± 0.1 (1.6–3); insideM1–1 width, 2.8 ± 0.2 (2.2–4.1); outsideM1–1 width, 6.9 ± 0.2 (6.6–7.2); insi- deM3–3 width, 4.1 ± 0.1 (2.9–5.3); crownsM1–2 length, 5.4 ± 0.2 (5.2–5.6); crownsM1–3 length, 6.5 ± 0.2 (6.3–6.7); upper molar alveolus, 6.8 ± 0.3 (5.9–8.7); length of incisive foramen, 13.5 ± 0.1 (10.3–17.2); bulla length, 5.1 ± 0.2 (4.4–6.7).

DISTRIBUTION

Melomys cervinipes is endemic to Australia, occurring along the eastern coast and subcoastal areas of Queensland and New South Wales ( Fig. 3 View Fig ). It is found from sea level (0 m) up to between 1,221 m (Mt. Elliot—Williams et al. 1993a) and 1,600 m ( Department of Environment and Heritage Protection 2017), ranging from tropical Northern Queensland, south of the Cape York Peninsula (10°45′0″S; 142°34′60″E) down to central New South Wales, about 50 km north of Sydney (33°25′48.15″S; 151°15′50.13″—Bryant and Fuller 2014; Fig. 3 View Fig ).

FOSSIL RECORD

Rodent fossils appear in Australia’s rock strata dating 5–4.5 million years ago ( Long et al. 2002; Rowe et al. 2008; Nilsson et al. 2010) and fossil evidence shows 3 waves of rodent migration into Australia: the 1st wave (± 4.5 million years ago) bringing the Conilurini; the 2nd wave (± 2 million years ago) bringing the Hydromyini and Uromyini ; and the 3rd wave (± 1.28–0.85 million years ago) bringing the genus Rattus ( Nilsson et al. 2010; Rowe et al. 2011). The mosaic-tailed rats were part of the 2nd wave occurring during the mid-Pleistocene, approximately 1.8 million years ago (Breed and Ford 2007; Nilsson et al. 2010).

Fossil records of Uromyine rodents in Australia are limited. Members of Uromys were recorded in a limestone quarry on the northeast face of Mount Etna (23°9′23.35″S; 150°28′49.90″E, about 25 km north of Rockhampton, Queensland—Hocknull et al. 2007), dated approximately 500,000 years old; however, the only definitive fossil record of Melomys is in late Pleistocene fossils from Pyramids cave (ca. 6.5 km north east of Buchan, Victoria; 37°26′59″S; 148°12′59″E—Mahoney 1965), dated approximately 33,000 –15,450 years old ( Wakefield 1972).

FORM AND FUNCTION

The dental formula of Melomys cervinipes is i 1/1, c 0/0, p 0/0, m 3/3, total 16 (Breed and Ford 2007). The upper molar alveolar pattern and alveolar length of M1 distinguish M. cervinipes from M. burtoni ( Knox 1978) . M. cervinipes shows 4 distinctive roots on M1 and M2, and 3 roots on M3, while M. burtoni shows a pattern of 5 roots on M1 and M2 and 3 roots on M3 ( Knox 1978). M1 alveolar length of M. cervinipes ranges between 3.1 and 3.7 mm compared to the smaller range of M. burtoni (2.4– 3.1 mm—Knox 1978). Upper incisors are opisthodont and the anterior palantine foramina is long, ending in line with the anterior face of the 1st molar ( Menzies 1996).

As is typical of most rodents, there are 2 clearly demarcated regions to the stomach: the forestomach (corpus) and the hindgut (antrum), with the corpus being considerably larger, with an extended fundic diverticulum for the potential storage of nonfibrous plant material (Breed and Ford 2007). The small intestine is approximately 50% of the total length of the intestinal tract (Breed and Ford 2007).

Brain weight for M. cervinipes is estimated at 1.9 g, accounting for about 2.7% of overall body mass ( Mace et al. 1981). According to Menzies (1996), the supraorbital crest extends as a weak ridge across the posterior surface of the cranium, fading as it reaches the posterior parietal margin. The parietal-squamosal suture turns away from the postorbital ridge, dipping downwards to form 90° ( Menzies 1996).

The gonads of Melomys resemble those of the brown rat Rattus norvegicus in their general morphology and histology (Taylor and Horner 1970). Adult females have 2 pairs of inguinal teats ( Harrison 1962; Calaby and Wimbush 1964; Barnett et al. 1977; Watts and Aslin 1981). Although considered rare, sexual quiescence in adult females is characterized by closing of the vagina and ovarian inactivity, with absence of mature follicles and large corpora lutea, presence of only small- and medium-sized (350–450 pm) follicles (with extensive atresia), and advanced luteal degeneration (Taylor and Horner 1970). The adult female bears 2 uterine horns, typical of murids. The ovary of nonpregnant females is also typical of most murids, with atresia of follicles at different stages of development and healthy mature follicles of various sizes (Taylor and Horner 1970). Ripe follicles are considerably smaller than newly formed corpora lutea, measuring only 750–800 pm in diameter, compared to 1,000 pm, respectively (Taylor and Horner 1970). The average ovulation rate is 3.25 follicles per estrus (range 2–4) and ovulatory activity and corpora luteal formation is evenly distributed between the 2 ovaries (Taylor and Horner 1970). Pregnant females bear considerably larger corpora lutea (ca. 1,700 pm) than nonpregnant females during the early stages of pregnancy, when average embryo crown-rump length is 37.5 mm (Taylor and Horner 1970). The corpus luteum decreases in size as the embryo increases in size, indicating a decrease in the function of the corpus luteum at this time (Taylor and Horner 1970). Larger follicles are atretic (Taylor and Horner 1970). The ovaries of juvenile females are characterized by naked peripheral ova, numerous small- and medium-sized follicles (approximately 475 pm), and extensive atresia (Taylor and Horner 1970).

Adult breeding males have scrotal or inguinal testes (mean = 2.78 g—Breed and Taylor 2000), which are relatively large in relation to body size for a murid (Breed and Taylor 2000), being 2% of the body mass ( Breed 1997a). Nonbreeding males show some regression of the testes and accessory sex glands (Taylor and Horner 1970). The glans penis is morphologically similar to other murids ( Breed 1986). It is relatively long (mean length= 7.2 mm), being 0.7–4.7 mm longer than 19 other species of Australian rodent, while the mean maximum width is 0.1–2.1 mm wider than 20 other Australian murids (mean = 3.2 mm—Mor-rissey and Breed 1982). Although the length and maximum width of the glans penis is greater in M. cervinipes than M. burtoni , the width near the outer rim is 0.3 mm narrower (mean = 2.1 mm— Morrissey and Breed 1982). Small spines are absent from the base of the glans penis, but are visible near the tip, and epidermal folding is evident (Morrissey and Breed 1982). The proximal baculum is short and wide (mean ± SD: length = 4.3 ± 0.3 mm; width = 2.6 ± 0.2 mm; length:width ratio = 1.6— Breed 1986). The large (mean: 13.1 mm, range: 9.3–19.1 mm—Taylor and Horner 1970), well-developed saccular seminal vesicles have coagulating glands lying on the inner curves ( Breed 1986) and the seminal vesicles are bound to the prostate at the base. Active spermatogenic seminiferous tubules have an average diameter of 136 μm (114–152 μm), while the lumina of the epididymal tubules, which are lined with pseudostratified ciliated columnar epithelium, averages 137 μm (100–180 μm—Taylor and Horner 1970). In contrast, inactive seminiferous tubules and the lumina of the epididymal tubules average 75 μm (58–96 μm) and 20 μm (10–30 μm), respectively, with no active spermatogenesis (Taylor and Horner 1970). Male accessory glands include the following: 1 pair of small medial ventral prostates ( Breed 1986); 1 small pair of dorsolateral prostates, with ducts entering the urethra on the ventrolateral surface ( Breed 1986); 1 typical pair of dorsal prostates ( Breed 1986), with numerous acini (Taylor and Horner 1970); 1 pair of Cowper’s glands (mean diameter = 2.7 mm, range = 1.8– 3.6mm—Taylor and Horner 1970); a compact collection of ampullary gland tubules lying toward the distal end of the vas deferens ( Breed 1986); 1 pair of bulbourethrals ( Breed 1986); preputial glands are absent (Taylor and Horner 1970; Breed 1986), which is common to the Uromyini ( Breed 1986) . Sperm length averages 107 μm (Breed and Taylor 2000) and the falciform sperm head is more complex than that of Australasian Rattus , with 2 additional, elaborate F-actin containing processes (ventral) extending from the upper concave surface (Breed and Sarafis 1978; Breed 1984; Breed and Aplin 1994; Breed 1997b), joining at the base ( Breed 1997b). Although the apical hook ultrastructural organization resembles the falciform spermatozoa of Rattus , there are 2 ridges of subacrosomal material along the upper convex margin of the nucleus ( Breed 1984; Breed and Leigh 1991; Breed 1997b). Juvenile males have smaller testes than adult males, which are situated in the lower abdominal position, and spermatogenesis, if present, does not progress beyond the primary spermatocyte stage (Taylor and Horner 1970). The average diameters of the seminiferous tubules (mean = 58 μm; range = 48–80 μm) and the tubular lumina (mean = 21 μm; range = 10–50 μm) are small, as are the accessory sex glands (Taylor and Horner 1970). The seminal vesicles are small (mean = 2.8 mm) and are generally nonsecretory in nature, while the luminar area is enclosed in an extensive bed of connective tissue, which is minimal in adults (Taylor and Horner 1970). The juvenile prostate has distinct, but small and simple, acini lined with pseudostratified low columnar epithelium and the Cowper’s glands are considerably smaller than adults, averaging 0.75 mm in diameter (Taylor and Horner 1970).

Mean ± SE blood chemistry values were: glucose (4.23 ± 0.19 mmol/l; n = 31), corticosterone (655 ± 75.96 ng / ml; n = 38), and testosterone (0.1 ± 0.01 ng /ml; n = 33— Turner 2015). The mean ± SE percentages (%) of 4 metabolites obtained from M. cervinipes (n = 4) injected with 3 doses (5, 25, and 100 mg /kg, respectively) of [14 C] phenol were: quinol glucuronide (10.7 ± 2.8, 11.3 ± 4.0, 23.1 ± 1.1), phenyl glucuronide (66.7 ± 4.1, 55.3 ± 4.3, 55.4 ± 2.5), quinol sulfate (1.3 ± 0.1, 1.1 ± 0.1, 3.5 ± 0.7), and phenyl sulfate (16.4 ± 4.4, 14.2 ± 6.8, 7.8 ± 2.9— Baudinette et al. 1980).

ONTOGENY AND REPRODUCTION

Sexual maturity in Melomys cervinipes generally occurs at approximately 45–60 g body weight (Taylor and Horner 1970; Barnett et al. 1977) and can be estimated when combined headbody length (excluding the tail) reaches 95–120 mm (Taylor and Horner 1970). The adult pelage is nearly completely attained by the time of sexual maturity (Taylor and Horner 1970). Sexual maturity in males is clearly observed when the testes are descended ( Barnett et al. 1977) and testis length distinguishes spermatogenic individuals from sexually inactive individuals due either to immaturity or to regression (Taylor and Horner 1970). Testes measuring 12–14 mm signify sexual maturity (Taylor and Horner 1970).

Sexual maturity is observed in females by the presence of prominent nipples ( Barnett et al. 1977) and a perforate vagina (Taylor and Horner 1970), which occurs at about 80 days (75– 85— Breed 1979). In addition, milk can be expressed easily from lactating females ( Wood 1971), also providing an indicator of breeding condition. Females are polyestrous (Taylor and Horner 1970) and Breed (1978a) noted a considerably long cycle of 10–24 days (average 17), which could be associated with higher peripheral levels of progesterone ( Breed 1978b; Watts and Kemper 1989). Breed (1978b) suggested 1 day of proestrus, 1–3 days of estrus, and between 6 and 19 (mean ± SE: 14.3 ± 0.6) days of diestrus. Females show spontaneous ovulation, suggesting that there is no distinct breeding season (Taylor and Horner 1970; Kemper 1980).

Breeding tends to increase during the wet season (Breed and Ford 2007). However, this is highly variable from year to year ( Wood 1971), as for other Melomys species (e.g., M. burtoni — Taylor and Horner 1970). Breeding generally commences in late spring and summer (September–February) in the more southern areas of Queensland (Stradbroke to Mackay—McDougall 1946; Taylor and Horner 1970; Wood 1971), and extends into autumn and winter (March–August) in the northern regions of Queensland (Mossman to Cooktown—Lönnberg and Mjöberg 1916; Taylor and Horner 1970). Wood (1971) suggests that males and females form stable breeding pairs.

Gestation lasts approximately 27–40 days ( Crichton 1969; Breed 1979; Watts and Aslin 1981; Sutherland and Dickman 1999), one of the longest among native Australian rodents ( Breed 1978a). Age at first reproduction is approximately 7 months (Nowak and Paradiso 1983; Strahan 1983). One of us (TLR) has observed that mass is not necessarily a good predictor of age at first reproduction as there is high individual variation in body mass both within and between populations. In the southern regions, young have been observed in summer (early Novemberearly January in southeastern regions of Queensland—Taylor and Horner 1970; October and February in northeastern New South Wales—Barnett et al. 1977), although birthing can occur later (late February–April in Mackay—Taylor and Horner 1970). Although breeding can take place within the same season of birth ( Wood 1971), generally breeding does not commence until the following year ( Freeland 1972; Watts and Kemper 1989). Taylor and Horner (1970) suggest that M. cervinipes may show postpartum estrous, although this requires further investigation.

Litter size ranges from 2 to 4 (Lönnberg and Mjöberg 1916; McDougall 1946; Davies 1960; Keith 1968; Taylor and Horner 1970; Wood 1971; Breed 1979; Watts and Kemper 1989), with an average of 1.8 ( Wood 1971), and generally the sex ratio of young born into a population is 50:50 ( Wood 1971). Young are precocious and relatively large at birth (about 5 g and 50 mm— Watts and Aslin 1981), with fine, dorsally pigmented hair. Incisor teeth are developed (Calaby and Wimbush 1964), with early terminal modification as grasping rather than gnawing structures ( Lawrence 1941; Hamilton 1953; Calaby and Wimbush 1964; Taylor and Horner 1970) to facilitate nipple clinging (Lönnberg and Mjöberg 1916; Gard 1935; McDougall 1944; Davies 1960; Taylor and Horner 1970). Nipple clinging likely arose early in the evolution of the mosaic-tailed rats (Calaby and Wimbush 1964) and, given the high occurrence of nipple clinging behavior in the Muridae in general, this trait is likely ancestral to the family ( Gilbert 1995). Numerous hypotheses have been proposed to explain the evolution of nipple clinging in the murids, specifically M. cervinipes , such as predator avoidance ( Vestal 1938; Egoscue 1962; Taylor and Horner 1970) and sibling competition ( Gilbert 1995). Young are fully furred with eyes open by 10 days and can be weaned at 20 days, indicating relatively rapid development (Watts and Aslin 1981). Mothers actively retrieve young back into the nest (Watts and Aslin 1981) and one of us (TLR) has observed that young will nipple cling beyond weaning if possible. This mode of reproduction suggests a prolonged prenatal contribution of care, with a relatively standard contribution to postnatal care (Taylor and Horner 1970).

ECOLOGY

Population characteristics. ―Average population density for Melomys cervinipes has been estimated between 0.08 and 0.40 individuals/ha in various sized areas and forest fragments on the Atherton Tablelands of Queensland ( Leung et al. 1993) and between 0.88 and 1.27 individuals/ha in sclerophyll forests of South East Queensland (S. Burnett, in litt.). Abundance increases in forests with large trees, vines, and leaf litter ( Wood 1971; Barnett et al. 1978), and also increases as the quantity of climbing plants, subcanopy, and ground cover increases, providing valuable food resources ( Laurance 1994; Williams and Marsh 1998; Williams et al. 2002). Abundance can be limited by the diversity of canopy tree species (Rader and Krockenberger 2006). Interestingly, while Leung et al. (1993) found that relative density is proportional to forest area, suggesting that population density is relatively consistent between areas, other studies have found that fragmentation increases population size ( Laurance 1994; Cox et al. 2003). Subsequently, M. cervinipes is more abundant in patches and forest edges than in continuous vine forest ( Goosem 2000), most likely due to increased abundances of vines and other climbing plants that assist foraging and climbing behavior ( Wood 1971; Laurance 1994; Cox et al. 2003; Moore and Burnett 2008). Indeed, Barnett et al. (1978) and Wood (1971) noticed increased abundance with increasing liana density. However, fragmentation limits dispersal between forest patches by opening up space with little overhead cover ( Bentley 2008; Elmouttie 2009), potentially exposing individuals to greater predation risk.

Space use. ―Typically, in the northernmost parts of its range, Melomys cervinipes occurs predominantly in dark, cool, and damp conditions characteristic of closed continuous forest ( Wood 1971; Barnett et al. 1978; Watts and Aslin 1981; Leung et al. 1993; Rader and Krockenberger 2006) but also occurs in rainforest fragments ( Laurance 1992, 1994; Goosem 2000) and deciduous vine thickets ( Williams et al. 1993b). Progressing south, M. cervinipes becomes less restricted in habitat preferences and is found in wetter, open forests (Watts and Aslin 1981; Peeters et al. 2014), wet sclerophyll to subtropical rainforest ( Barnett et al. 1978), warm-temperate rainforests (including fragments—Cox et al. 2003), grassy open forest adjacent to rainforest ( Dwyer et al. 1979; Woodall 1989), open shrubland ( Woodall 1989), woodlands ( Harrison 1962), often dominated by dry, tall eucalypts on sandy soil (Taylor and Horner 1970; Peeters et al. 2014), closed palm forest ( Martin 1975), tropical and subtropical closed forest (Watts and Aslin 1981), coastal mangrove forests (Lavery and Johnson 1974), and even cane fields adjacent to forested areas (up to 200 m into the field—McDougall 1944). Woodall (1989) recorded captures of M. cervinipes on Carlisle Island (20°47′S, 149°17′E, 35 km northeast of Mackay, Queensland) in closed forest dominated by Bosistoa medicinalis , open forests dominated by Eucalyptus alba , E. polycarpa , E. tesselaris , Acacia solandri , and Casuarina equisetifolia , and open shrubland dominated by Aglaia , Crinum , Macaranga, Scaevola , Sophora , Celtis , Olea , and Cycas . Hockings (1981) did not capture M. cervinipes in any habitat at Beerwah (26°51′26.28″S, 1152°57′18.72″E) or in scribbly gum- Banksia aemula habitat in the Cooloola State Forest (26°3′27.5112″S, 153°2′33.5256″E), suggesting landscape variation in distribution. The canopy floor and different vertical forest layers (at least up to 16 m—Rader and Krockenberger 2006) are used. M. cervinipes spends between 30% and 90% of the time travelling in the canopy, with large amounts of individual variation (Rader and Krockenberger 2006).

Within a habitat, individuals only travel short distances ( Elmouttie 2009).Although long-distance movements of between 350 and 1,500 m have been recorded, range lengths tend to be an order of magnitude smaller, ranging up to about 83 m for males and 81 m for females in New South Wales ( Barnett et al. 1978) and 70.7 m for adults in Queensland ( Bentley 2008). Range length is generally shorter in summer (mean ± SE: 11.9 ± 1.4 m) compared to winter (mean ± SE: 17.2 ± 3.9 m—Bentley 2008), perhaps due to increased resource abundance in the summer months, reducing the need to travel to find food. The home range is relatively small, averaging 0.42 ha (males = 0.31–0.67 ha; females = 0.21–0.5 ha—Rader and Krockenberger 2006), with no significant difference between the sexes ( Wood 1971; Rader and Krockenberger 2006; Bino et al. 2014; but see Smith 1985). The core area of activity is smaller, averaging approximately 0.091 ha (Rader and Krockenberger 2006). Home ranges of individuals, both within and between sexes, overlap ( Smith 1985) and there is little evidence of territorial exclusion, including a lack of correlation between body size and territory size (Rader and Krockenberger 2006). Body mass is negatively correlated with tree species diversity, suggesting that larger individuals occupy areas with lower canopy tree diversity (Rader and Krockenberger 2006). Rader and Krockenberger (2006) suggest that these areas often contain denser layers of subcanopy, understory, and vine species, potentially providing greater cover from predation.

In captivity, life span is approximately 2 years ( Hayes et al. 2006). In the wild, individuals are known to survive to a 2nd breeding season ( Wood 1971); thus, longevity is estimated to be between 1 and 2 years ( Laurance 1991). Adult population sex ratios average 50:50 (Taylor and Horner 1970; Wood 1971; Smith 1985; Horskins 2005).

Diet. ―The diet of Melomys cervinipes is characteristic of a generalist, consisting primarily of foliage and vegetation ( Harrison 1962), and it has also been reported to feed on fruits and seeds, as well as fungi, insects, and flowers ( Wood 1971; Rader and Krockenberger 2006; Elmouttie 2009; Elmouttie and Mather 2012), as well as human food products (S. Burnett, in litt.). This is supported by the morphology of the forestomach (Breed and Ford 2007). M. cervinipes climbs to access fruits, flowers, and nuts in the forest canopy (Rader and Krockenberger 2006). Due to the wide habitat and geographical distribution of M. cervinipes , there is evidence of regional and habitat differences in diet. For example, Vernes and Dunn (2009) found that fungi comprised 67% of the diet of M. cervinipes in heath-wet sclerophyll, whereas fungi comprised only 10% of the diet of individuals occurring in rainforests. It has also been suggested that animals living in edges have a higher proportion of fruits, leaves, and flowers in their diet due to the high abundance of these resources in these types of areas ( Laurance 1994).

Diseases and parasites. ― Melomys cervinipes carries several internal and external disease-causing agents. Leptospirosis is a zoonotic emerging infectious disease (Brandling-Bennett and Pinheiro 1996; Levett 1999) caused by pathogenic leptospire bacteria ( World Health Organization 2003). Internally, M. cervinipes is a known urinary carrier of 3 leptospirosis Leptospira serovars, namely celledoni in the Celledoni serogroup ( Emanuel et al. 1964), zanoni in the Pyrogenes serogroup ( Biosecurity Australia 2000), and is considered to be a maintaining host of the bindjei serovar in the Canicola serogroup (along with M. burtoni — Battey et al. 1964). In addition, antibodies to serotype L. pomona have been found in the sera of M. cervinipes , although the strain itself was not isolated and M. cervinipes is not identified as a urinary carrier ( Battey et al. 1964). Six other bacteria found in M. cervinipes are Mycoplasma haemomuris ( Mackerras 1958) , Spirillum minus ( Cook et al. 1967) , Eperythrozoon coccoides ( Cook et al. 1967) , Brucella suis type 3 ( Cook et al. 1966, 1967), Coxiella burnetii ( Cook et al. 1967) , and the TVS1 and TVS2 strains of Orientia tsutsugamushi , of which the TSV2 strain is highly virulent ( Cook et al. 1967; Campbell and Domrow 1974; Glazebrook et al. 1978).

Melomys cervinipes is also parasitized by at least 35 species of internal parasites from 7 orders. These include (compiled from Johnston and Mawson 1941; Mackerras 1958; Sprent and Mines 1960; Mawson 1961; Sprent 1963; Sprent and McKeown 1967; Bhaibulaya 1968, 1979; Freeland 1983; Beveridge 1985; Hugot and Quentin 1985; Spratt and Singleton 1986, 2001; Singleton et al. 1991; Gibbons and Spratt 1995; Smales 1997, 2009; Smales et al. 2004; Spratt 2008): Order Cyclophyllidea (2 species: Bertiella and Raillientina celebensis ), Order Panagrolaimida (1 species: Strongyloides ), Order Plagiorchiida (1 species: Platynosomum australiense ), Order Porcephalida (1 species: Linguatula serrata ), Order Rhabditida (16 species: Angiostrongylus mackerrasae, Chisholmia bainae , C.mawsonae, Equilophos polyrhabdote, Hepatojarakus fasciatus , H. pycnofasciatus , Mammanidula melomyos , Nippostrongylus magnus , N. typicus , Odilia brachybursa , O. emanuelae , O. mackerrasae , O. melomyos , Parasabanema praeputiale , Peramelistrongylus , and P. skedasto ), Order Spirurida (10 species: Allodapa, Cercopithfilaria johnstoni, Heterakis spumosa , Mastophorus muris , Monanema australis , Ophidascaris robertsi , Physaloptera banfieldi , Polydelphis anoura , Syphacia darwini , and Toxocara mackerrasae ), Order Trichocephalida (3 species: Calodium hepatica , Capillaria , and Trichurus muris ) and unidentified microfilaria ( Mackerras 1962). Freeland (1983) suggested that Ophidascaris robertsi does not readily infect M. cervinipes in the natural environment, although M. cervinipes does demonstrate susceptibility in a laboratory environment.

Externally, as with other rodents, M. cervinipes is subject to mite, tick, flea, and louse infestation. Forty-eight species of external parasite have been recorded on M. cervinipes from 5 orders. These include (compiled from Radford 1943, 1954; Domrow and Smith 1955; Roberts 1960, 1970; Domrow 1960, 1961, 1962, 1967, 1971, 1978, 1987, 1991; Kuhn and Ludwig 1966; McKenzie et al. 1976; Doube 1979; Fain and Lukoschus 1981; Domrow and Lester 1985): Order Ixodida (3 species: Haemaphysalis humerosa , Ixodes holocyclus , and I. tasmani ), Order Mesostigmata (12 species: Domrownyssus dentatus , Haemolaelaps domrowi , Laelaps assimilis , L.echidinus , L.mack - errasi, L. nuttalli , L. rothschildi , L. southcotti , Mesolaelaps anomalus , M. bandicoota, Paramelaelaps bandicoota , and Trichonyssus praedo ), Order Psocodea (1 species: Hoplopleura ), Order Sarcoptiformes (3 species: Notoedres muris , Murichirus enoplus , and M. lobatitarsis ), and Order Trombidiformes (33 species: Ascoschoengastia indica , A. rattus , Eutrombicula hirsti , Guntheria andromeda , G. bamaga , G. cassiope , G. coorongensis , G. derrick , G. dumosa , G. heaslipi , G. innisfailensis , G. kallipygos , G. lappacea , G. mackerrasae , G. petulans , G. pseudomys , G. scaevola , G.shieldsi , G. smithi , G.wongabelensis , Helenicula kohlsi , Leptotrombidium delicense , Neotrombicula antechinus , Odontocarus , Paraspeleognathopsis , Schoutedenichia emphyla , Walchia , W. fuller , and W. morobensis ). Domrow (1967) reported G. antipdoianumi , G. queenslandica , P. bakeri , and Radfordia fanningi from M. cervinipes originating in grassland. Given the generally sharply defined habitat contrast between M. cervinipes and M.burtoni , it is likely that the host species was misidentified.

Melomys cervinipes is also known to carry at least 5 different species of keratinophilic fungi, namely Arthroderma curreyi , A. cuniculi , A. cajetani , Chrysosporium ( Rees 1967) , and A. tuberculatum ( Hubalek 2000) .

Interspecific interactions. ― Melomys cervinipes is sympatric over parts of its range with 2, almost morphologically indistinguishable species, namely M. burtoni (Taylor and Horner 1970; Watts and Aslin 1981; Frost 2008) and a currently undescribed mosaic-tailed cryptic taxon, species nova ( Bryant et al. 2011). This taxon is not monophyletic with any Melomys (Australian or New Guinean) and is considered a sister taxon to Melomys and Solomys ( Bryant et al. 2011) . M. cervinipes and M. burtoni are generally sharply segregated in space ( Smith 1985), utilizing different habitats (rainforest versus grassland). M. cervinipes currently possesses an allopatric distribution to M. capensis , with M. capensis being restricted to the Cape York Peninsula and M. cervinipes occurring south of this region (Bryant and Fuller 2014).

Melomys cervinipes commonly occurs with the Cape York rat Rattus leucopus in the same habitat, suggesting limited competition ( Laurance 1994). Co-occurrence is likely possible because the Cape York rat rarely leaves the forest floor, whereas M. cervinipes is scansorial ( Wood 1971). In contrast, M. cervinipes abundance is lower in habitats occupied by the bush rat Rattus fuscipes and giant white-tailed rat Uromys caudimaculatus , suggesting competitive exclusion as a consequence of diet (both consume seeds, nuts, stems, and leaves—Watts 1977) or space use (both species are scansorial—Laurance 1992) by these larger-bodied species. M. cervinipes also cooccurs with several other mammal species ( Harrison 1962; Williams et al. 1993 a, 1996; Goosem 2000; Harrington et al. 2001; Jackson 2001; Rader and Krockenberger 2006; Vernes et al. 2006; Rowland 2015; Smith et al. 2017): feathertail glider Acrobates pygmaeus , rufous bettong Aepyprymnus rufescens , rusty antechinus Antechinus adustus , yellow-footed antechinus A. flavipes, Atherton antechinus A. godmani , brown antechinus A. stuartii , northern bettong Bettongia tropica , long-tailed pygmy possum Cercartetus caudatus , eastern pygmy possum C. nanus , striped possum Dactylopsila trivirgata , Bennett’s tree-kangaroo Dendrolagus bennettianus , Lumholtz’s treekangaroo D. lumholtzi , lemuroid ringtail possum Hemibelideus lemuroides , water rat Hydromys chrysogaster , musky rat-kangaroo Hypsiprymnodon , northern brown bandicoot Isoodon macrourus , long-nosed bandicoot Perameles nasuta , spectacled hare-wallaby Lagochestes conspicillatus, brown hares Lepus capensis , agile wallaby Macropus agilis , antilopine kangaroo M. antilopinus , eastern grey kangaroo M. giganteus , parma wallaby M. parma , whip-tail wallaby M. parryi , common wallaroo M. robustus , red-necked wallaby M. rufogriseus , black-footed tree-rat Mesembriomys gouldii , house mouse M. musculus , platypus Ornithorhynchus anatinus , European rabbit Oryctolagus cuniculus , yellow-bellied glider Petaurus australis , mahogany glider P. gracilis , sugar glider P. breviceps , squirrel glider P. norfolcensis , greater glider Petauroides volans , allied rock-wallaby Petrogale assimilis , unadorned rock-wallaby P. inornata , Godman’s rock-wallaby P. godmani, Mareeba rock-wallaby P. mareeba , Sharman’s rock-wallaby P. sharmani , brush-tailed phascogale Phascogale tapoatafa, koala Phascolarctos cinereus , long-tailed planigale Planigale ingrami , common planigale P. maculata , prehensile-tailed rat Pogonomys mollipilosus , long-nosed potoroo Potorous tridactylus , common ringtail possum Pseudocheirus peregrinus , green ringtail possum Pseudocheirops archeri, Daintree River ringtail possum Pseudochirulus cinereus, Herbert River ringtail possum P. herbertensis , delicate mouse Pseudomys delicatulus , eastern chestnut mouse P. gracilicaudatus , swamp rat Rattus lutreolus , brown rat, black rat R. rattus , canefield rat R. sordidus , pale field rat R. tunneyi , white-footed dunnart Sminthopsis leucopus , stripe-faced dunnart S. macroura , common dunnart S. murina , red-cheeked dunnart S. virginiae , feral pig Sus scrofa, short-beaked echidna Tachyglossus aculeatus , red-legged pademelon Thylogale stigmatica , red-necked pademelon T. thetis , mountain brushtail possum Trichosurus caninus , coppery brushtail possum T. johnstonii , common brushtail possum T. vulpecula , masked white-tailed rat Uromys hadrourus , swamp wallaby Wallabia bicolor , and common rock rat Zyzomys argurus . M. cervinipes also has numerous natural predators, including the dingo Canis lupus dingo ( Vernes et al. 2001; Hayes et al. 2006), spotted tail quoll Dasyurus maculatus ( Hayes et al. 2006; Moore and Burnett 2008), northern quoll D. hallucatus (Moore and Burnett 2008) , sooty owl Tyto tenebricosa ( Holmes 1994; Moore and Burnett 2008), lesser sooty owl T. multipunctata (Moore and Burnett 2008; McDonald et al. 2013), southern boobook Ninox boobook (Moore and Burnett 2008) , Amethystine python Morelia amethistina (Moore and Burnett 2008) , carpet python M. spilota variegata ( Hayes et al. 2006; Moore and Burnett 2008), spotted python Antaresia maculosa (Moore and Burnett 2008) , and red-bellied black snake Pseudechis porphyriacus ( Hayes et al. 2006) . The feral cat Felis catus is also a predator of M. cervinipes (Moore and Burnett 2008) .

Melomys cervinipes is important for increasing germination of rainforest fruits (by a factor of 3.5) due to its removal of the pericarp, suggesting it is a mutualistic frugivore with fruiting rainforest tree species (Elmouttie and Mather 2012). Out of 19 rainforest fruit species presented to both M. cervinipes and bush rats, 16 (84% of species) showed increased germination rates, whereas the germination rates of Neisosperma poweri , Beilschmiedia recurva , and Endiandra monothyra sub monthyra were not affected (Elmouttie and Mather 2012). Interestingly, as the bush rat does not feed on either Syzgium gustavioides or Beilschiedia bancrofti (Elmouttie and Mather 2012) , M. cervinipes could be particularly important for these species. Although M. cervinipes has been reported to occur in sugarcane Saccharum , it is rarely captured in this habitat type, and is thus unlikely to be a major crop pest, unlike M. burtoni ( Dyer et al. 2011) .

Miscellaneous. —Livetrapping with a bait mixture of peanut butter, honey, vanilla essence, and rolled oats ( Rowland 2015) is suitable for Melomys cervinipes , although it will still enter traps baited only with rolled oats and vanilla essence ( Laurance 1992), peanut butter and rolled oats ( Barnett et al. 1978), or even linseed oil-soaked cardboard ( Horskins 2005). Trapping success is approximately 2.23 times higher in arboreal traps than terrestrial traps ( Laurance 1992).

BEHAVIOR

Melomys cervinipes is nocturnal (Taylor and Horner 1970; Wood 1971), with variations in activity depending on time of year and moonlight ( Wood 1971). Most activity takes place soon after sunset, between 1770 and 2300h, and again before sunset, between 0200 and 0500 h. However, M. cervinipes have been captured at all hours throughout the night (T. Stewart, unpubl. data). There is no discernable change in activity between seasons ( Wood 1971).

Melomys cervinipes is scansorial (Taylor and Horner 1970; Watts and Aslin 1981), favoring trees with epiphytic or attached vegetation growing on them (e.g., vines, creepers—Wood 1971). M. cervinipes makes extensive use of the arboreal environment for foraging (Rader and Krockenberger 2006) and nesting ( Wood 1971). Nests are located in the center of the home range, both on, and above, the ground (between 0.8 and 16 m), with both sexes using multiple nests (up to 2) simultaneously (Rader and Krockenberger 2006). Ground nest are usually located in burrows and hollows. Arboreal nests may be constructed of leaves, such as Calamus and Pandanus (Moore and Burnett 2008) . M. cervinipes also utilizes grass trees Xanthorrhoea for food and nesting ( Williams et al. 1993a). Nests have also been associated with human materials (e.g., beneath sheets of corrugated iron, inside furniture, etc.—S. Burnett, in litt.).

Olfactory recognition of mammalian predators is observed during the late wet season (May—Hayes et al. 2006). Interestingly, M. cervinipes avoids both familiar (quoll, dingo) and unfamiliar predators (Tasmanian devil Sarcophilus harrisii , red fox Vulpes vulpes ) during this time ( Hayes et al. 2006). No avoidance of predator cues, apart from quoll cues, is observed in the late dry season (October–November) and M. cervinipes does not appear to avoid reptilian predator cues (carpet python— Hayes et al. 2006). Hayes et al. (2006) suggested that this recognition and avoidance pattern occurs during the late wet season because there are more juveniles, which could be beneficial for minimizing predation risk and maximizing survival. M. cervinipes may utter loud distress calls upon handling (Meek and Peak 2008; T. L. Rymer, in litt.).

Melomys cervinipes displays behavioral syndromes (i.e., personality), with some individuals being consistently bolder than others ( Turner 2015). Activity in the open field was found to be repeatable over a 24-h period, and activity in the open field was correlated with activity in both novel object and predator avoidance tests ( Turner 2015). Interestingly, when exposed to a handling stress, bolder animals show increased testosterone production, rather than inhibition, as should occur with increased glucocorticoid synthesis (Retana-Márquez et al. 2003; Hardy et al. 2005), compared to more shy individuals ( Turner 2015). However, testosterone is energetically expensive to produce, and these bolder animals consequently show decreased glucose concentrations under stressful situations ( Turner 2015). Anxiety behavior, as measured by the time spent active in the open arms of a plus maze, was not correlated with corticosterone, a stress glucocorticoid, production ( Charmandari et al. 2005), suggesting decoupling of personality traits ( Turner 2015). This is predicted in complex environments, such as tropical rainforests, where habitat complexity may select for both behavioral flexibility (associated with reactive coping styles) and boldness (associated with proactive coping styles—Delarue et al. 2015).

GENETICS

The genus Melomys in Australia and New Guinea is monophyletic, excluding Paramelomys ( Bryant et al. 2011) , and is paraphyletic with Solomys (Watts and Baverstock 1995; Rowe et al. 2008; Bryant et al. 2011). Indeed, Menzies (1996) suggested that Paramelomys is a plesiomorphic sister group to Melomys . Genetic studies suggest that Melomys and Solomys diverged about 2.3 million years ago ( Bryant 2013). This close relationship between Melomys and Solomys is also evidenced in the region encoded by exon 6 of Zp3 (zona pellucida glycoprotein 3), where both groups share a histidine in position 298 ( Swann et al. 2007). The 3 extant Australian Melomys species, and the extinct M. rubicola , shared a common ancestor approximately 1.3–1.5 million years ago, after which M. burtoni diverged from M. cervinipes , M. rubicola , and M. capensis ( Bryant 2013; Bryant and Fuller 2014).

Melomys cervinipes has a diploid number (2n) of 48 chromosomes ( Baverstock et al. 1980), although the modal number of chromosomes can differ cell to cell, and up to 12 additional B chromosomes may be present ( Baverstock et al. 1977). Chromosome pair 1 of M. cervinipes is a large subacrocentric chromosome in contrast to pair 1 in M. burtoni which is a large telocentric chromosome ( Baverstock et al. 1980).

Melomys cervinipes is split into 3 divergent genetic clades (northern, central, and southern—Bryant and Fuller 2014), and the phylogeography reflects multiple instances of allopatric divergence. One product of these successive divergence events is that northern and southern lineages have fixed differences across 10% of loci ( Baverstock et al. 1980). The northern clade is distributed between the Burdekin gap and Laura Basin in north Queensland, and is closely related to M. rubicola–M. capensis clade in the northern regions, having diverged approximately 1.2–0.77 million years ago ( Bryant et al. 2011; Bryant and Fuller 2014), possibly due to isolation across the Normanby gap in far north Queensland ( Bryant et al. 2011). Roughly, the northern lineage corresponds to populations north of Townsville in the Wet Tropics of far north Queensland ( Campbell 1996). Although M. cervinipes is phylogenetically close to M. capensis , it is electrophoretically distant, demonstrating rapid protein evolution in comparison to M. capensis and M. burtoni ( Baverstock et al. 1980) . Secondary contact has been documented between the northern and central lineages on the northern side of the Burdekin gap, where both occur in sympatry (Bryant and Fuller 2014). The central and southern lineages diverged across the Brisbane Valley Barrier (which continues to limit their distribution) approximately 0.94–0.49 million years ago ( Bryant et al. 2011; Bryant 2013; Bryant and Fuller 2014). The central lineage ranges from the northern side of the Burdekin gap to the Brisbane Valley Barrier, below which the southern lineage occurs ( Bryant 2013; Bryant and Fuller 2014).

A currently undescribed taxon designated species nova occurs in sympatry with M. cervinipes , having been recorded in the Tully region, Wooroonooran National Park ( Bryant et al. 2011) and Mount Lewis in north Queensland ( Bryant 2013). The species shares a most recent common ancestor with all Australian and New Guinean Melomys and Solomys , although is morphologically indistinguishable from M. cervinipes and is not monophyletic with Melomys from either Australia or New Guinea ( Bryant et al. 2011). Species nova is highly genetically distinctive from members of the Melomys genus (0.7–5% divergent with a 1-base pair indel in the AP5 intron) and is also divergent from sympatric M. cervinipes (0.3–3.7% divergent—Bryant et al. 2011). It is suggested that species nova diverged from the Melomys–Solomys clade approximately 2.5 million years ago ( Bryant et al. 2011). The presence of 7 fixed genetic substitutions and 2 fixed indels (in the nuclear loci) suggests reproductive isolation is occurring between M. cervinipes and species nova ( Bryant et al. 2011).

CONSERVATION

Melomys cervinipes is listed as “Least Concern” by the International Union for the Conservation of Nature and Natural Resources Red List (Burnett and Winter 2008) due to its wide distribution, apparent large population size, and lack of major threats (Burnett and Winter 2008). M. cervinipes utilizes closed forest environments, or forest fragments greater than 1 ha in area ( Cox et al. 2003), although it does occur in more open forests areas (S. Burnett, in litt.), disturbed forests and edges, often appearing at greater population densities in habitat fragments than unfragmented rainforest ( Laurance 1994). However, while M. cervinipes is capable of using habitat corridors for movement and gene flow, resulting in little genetic variation between fragmented populations ( Leung et al. 1993), it is inhibited from travelling between fragments by humanformed barriers, such as cleared areas, roads, and power line corridors ( Barnett et al. 1978; Goosem and Marsh 1997). Consequently, consideration on remaining patch size and connectivity is advisable when clearing forest inhabited by M. cervinipes .