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Phytogeographical Implication of Bridelia Will. (Phyllanthaceae) Fossil Leaf from the Late Oligocene of India

Abstract

Background

The family Phyllanthaceae has a predominantly pantropical distribution. Of its several genera, Bridelia Willd. is of a special interest because it has disjunct equally distributed species in Africa and tropical Asia i.e. 18–20 species in Africa-Madagascar (all endemic) and 18 species in tropical Asia (some shared with Australia). On the basis of molecular phylogenetic study on Bridelia, it has been suggested that the genus evolved in Southeast Asia around 33±5 Ma, while speciation and migration to other parts of the world occurred at 10±2 Ma. Fossil records of Bridelia are equally important to support the molecular phylogenetic studies and plate tectonic models.

Results

We describe a new fossil leaf of Bridelia from the late Oligocene (Chattian, 28.4–23 Ma) sediments of Assam, India. The detailed venation pattern of the fossil suggests its affinities with the extant B. ovata, B. retusa and B. stipularis. Based on the present fossil evidence and the known fossil records of Bridelia from the Tertiary sediments of Nepal and India, we infer that the genus evolved in India during the late Oligocene (Chattian, 28.4–23 Ma) and speciation occurred during the Miocene. The stem lineage of the genus migrated to Africa via “Iranian route” and again speciosed in Africa-Madagascar during the late Neogene resulting in the emergence of African endemic clades. Similarly, the genus also migrated to Southeast Asia via Myanmar after the complete suturing of Indian and Eurasian plates. The emergence and speciation of the genus in Asia and Africa is the result of climate change during the Cenozoic.

Conclusions

On the basis of present and known fossil records of Bridelia, we have concluded that the genus evolved during the late Oligocene in northeast India. During the Neogene, the genus diversified and migrated to Southeast Asia via Myanmar and Africa via “Iranian Route”.

Introduction

The family Phyllanthaceae has a predominantly pantropical distribution (with a few temperate elements) [1] (Figure 1) consisting of morphologically diverse, ∼60 genera and 2000 species. The family was separated from the Euphorbiaceae s.l. (sensu lato) on the basis of molecular data [2]. The pollen evidence indicates that the family became well diversified by the Eocene [3], [4]. Of its several genera, Bridelia Willd. is of a special interest because it has disjunct equally distributed species in Africa and tropical Asia i.e. 18–20 species in Africa and Madagascar (all endemic) and 18 species in tropical Asia (some shared with Australia) [5][7]. On the basis of molecular phylogenetic study on Bridelia, it has been suggested that the genus evolved around 33±5 Ma (i.e. the stem age) and radiated by the 10±2 Ma (i.e. the crown group) [8]. Fossil records of such taxon are equally important to support the molecular phylogenetic studies.

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Figure 1. Map showing the modern distribution of the family Phyllanthaceae and Bridelia [1], [64].

https://doi.org/10.1371/journal.pone.0111140.g001

In the present paper we describe a new leaf impression/compression of Bridelia from the late Oligocene (Chattian, 28.4–23 Ma; [9]) sediments of Makum Coalfield (27°15′–27° 25′ N), Assam, India (Figure 2) which was located at low palaeolatitude (i.e. 10°–15° N) during the period [10]. The suturing of the Indian plate with the Eurasian plate, during the aforesaid period, was not complete to facilitate the plant migration (Figure 3) [11][13]. An attempt has also been made to discuss its origin and dispersal.

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Figure 2. Simplified geological map of the Makum Coalfield, Assam, India showing the fossil locality (red circle) [65].

https://doi.org/10.1371/journal.pone.0111140.g002

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Figure 3. Map showing the fossil locality (yellow dot) in palaeogeographic map during the Oligocene [66].

https://doi.org/10.1371/journal.pone.0111140.g003

Regional geology

The Makum Coalfield is a well known basin having exposure of the late Oligocene sediments. The coalfield is important because (i) it is one of the largest coal producing basins in northeast India and (ii) it contains a well diversified low latitude palaeoflora [14][22]. Infact, there is no other Oligocene sedimentary basin in the Indian sub-continent which contains such a rich and diversified assemblage of fossil plants. The basin was situated at a low palaeolatitude i.e. ∼10°–15° N (Figure 3) [10] and the sediments were deposited in a deltaic, mangrove or lagoonal environment [15], [23][25]. The coalfield is made up of Baragolai, Ledo, Namdang, Tikak, Tipong and Tirap collieries, lies in between the latitudes 27° 15′–27° 25′ N and longitudes 95° 40′–95° 55′ E (Figure 2) and is located along the outermost flank of the Patkai range. On the southern and southeastern sides are the hills which rise abruptly to heights of 300–500 m from the alluvial plains of the Buri Dihing and Tirap rivers, respectively.

The fossils collected for the present study belong to the Tikak Parbat Formation being considered to be late Oligocene (Chattian, 28.4–23 Ma; [9]) in age on the basis of regional lithostratigraphy [26], remote sensing [27] and biostratigraphic controls [24].

The Tikak Parbat Formation constitutes alternations of sandstone, siltstone, mudstone, shale, carbonaceous shale, clay and coal seams [28]. However, the plant remains are mainly confined to the grey carbonaceous and sandy shales. The formation is underlain by 300 m of predominantly massive, micaceous or ferruginous sandstones that incorporate the Baragolai Formation, which is successively underlain by 1100–1700 m of thin-bedded fine-grained quartzitic sandstones with thin shale and sandy shale partings that constitute the Naogaon Formation [29]. Together the three formations represent the Barail Group (Figure 2). In this group, there is an upward trend of marine to non-marine palaeoenvironment which symbolizes the infilling of a linear basin on the eastern edge of the Indian plate. The detailed sedimentary information of the Tirap mine section was given by Kumar et al. [24].

Materials and Methods

Material for the present study was collected from the Tirap colliery of the Makum Coalfield, Tinsukia District, Assam. The prior permission was taken from the General Manager, Northeastern Coalfield, Margherita, Assam, India for the collection of fossil plants. The specimen was first cleared with the help of a fine chisel and hammer and then photographed in natural low angled light using 10 megapixel digital camera (Canon SX110). The terminology used in describing the fossil leaf is based on Hickey [30], Dilcher [31] and Ellis et al. [32]. Attempts were made to extract cuticle from the leaf but it did not yield. The permission was taken from the Directors, Forest Research Institute, Dehradun and the Botanical Survey of India, Kolkata for the herbarium consultation. The fossil plant was identified with the help of herbarium sheets of the extant plant available there. The type specimen (no. BSIP 40115) is housed in the museum of the Birbal Sahni Institute of Palaeobotany, Lucknow, India.

Nomenclature

The electronic version of this article in Portable Document Format (PDF) in a work with an ISSN or ISBN will represent a published work according to the International Code of Nomenclature for algae, fungi, and plants, and hence the new names contained in the electronic publication of a PLOS ONE article are effectively published under that Code from the electronic edition alone, so there is no longer any need to provide printed copies. The online version of this work is archived and available from the following digital repositories: PubMed Central, LOCKSS.

Results

Systematic description

Order. Malpighiales Juss. (1820) [33]

Family. Phyllanthaceae Martinov (1820) [34]

Subfamily. Phyllanthoideae Asch. (1864) [35]

Tribe. Bridelieae Müll. Arg. (1864) [36]

Genus. Bridelia Willd. (1806) [37]

Species. B. makumensis Srivastava and Mehrotra, sp. nov.

Figures. 4A, B, D; 5A, D

Holotype. Specimen No. BSIP 40115

Horizon. Tikak Parbat Formation

Locality. Tirap Colliery, Tinsukia District, Assam (27° 17′ 20″ N; 95° 46′ 15″ E)

Age. Late Oligocene (Chattian, 28.4–23 Ma)

Number of specimens studied. One.

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Figure 4. Bridelia leaves.

A. Fossil leaf of Bridelia makumensis sp. nov. showing shape, size and venation pattern. B. Text diagram of the fossil leaf showing craspedodromous and eucamptodromous venation (yellow and green arrows), secondary veins (red arrows) and percurrent, recurved and forked tertiary veins (blue, orange and black arrows). C. Modern leaf of Bridelia retusa showing craspedodromous and eucamptodromous venation (yellow and green arrows), secondary veins (red arrows) and percurrent and recurved tertiary veins (blue and orange arrows). D. Enlarged portion of the fossil leaf showing secondary veins (pink arrows), percurrent, recurved and forked tertiary veins (yellow, white and red arrows); predominantly alternate tertiary veins (orange arrow). E. Modern leaf of Bridelia retusa showing secondary veins (pink arrows); percurrent, recurved and forked tertiary veins (yellow, white and red arrows) Scale bar = 1 cm, unless mentioned.

https://doi.org/10.1371/journal.pone.0111140.g004

Description.

Leaf nearly complete, simple, symmetrical, microphyll, elliptic, preserved lamina length 5.2 cm (estimated lamina length 7.3 cm), maximum width near the middle portion 2.4 cm; apex not preserved but seems to be acute-obtuse; base slightly broken, asymmetrical, acute, normal; margin entire but slightly crenate seen on the distal portion, seemingly wavy; texture appearing chartaceous; attachment with petiole not preserved; venation pinnate, simple craspedodromous to eucamptodromous; primary vein stout in thickness, curved; secondary veins 11 pairs visible, 0.2–0.4 cm apart, predominantly alternate, angle of divergence moderate acute (48°–62°), smoothly and sometimes abruptly curved up near the margin, attachment with the primary vein normal, rarely decurrent; intersecondary veins absent; tertiary veins simple percurrent, recurved, forked, oblique to mid-vein, angle of origin AO, AA, AR, predominantly alternate, close; marginal ultimate venation fimbriate; quaternary veins orthogonal.

Affinities.

The characteristic features of the fossil leaf such as elliptic shape, crenate margin, craspedodromous to eucamptodromous venation, moderate acute angle of divergence of secondary veins, percurrent to recurved tertiary veins and fimbriate marginal venation suggest its affinity with Bridelia of the family Phyllanthaceae. A large number of species of Bridelia such as B. assamica Hook.f., B. cinnamomea Hook.f., B. glauca Blume, B. insulana Hance, B. ovata Decne. (syn. B. burmanica Hook.f.), B. retusa (L.) A. Juss. (syn. B. squamosa), B. stipularis (L.) Blume (syn. B. scandens), B. tomentosa Blume and the species of its sister genus Cleistanthus Hook.f. ex Planch such as C. collinus (Roxb.) Benth. ex Hook.f., C. malabaricus Müll.Arg. and C. monoicus (Lour.) Müll.Arg. were studied and compared in the herbarium of the Forest Research Institute, Dehradun and the Central National Herbarium, Howrah.

In B. assamica, B. cinnamomea, B. glauca, B. scandens and Cleistanthus monoicus the angle of divergence of secondary veins is narrow-moderate acute which is in contrast to the present fossil. In B. insulana, B. tomentosa, Cleistanthus collinus and C. malabaricus the distance between the two secondary veins is greater than the present fossil. In the venation pattern the fossil shows maximum similarity with B. retusa (Figure 4C, E) and B. stipularis (Figure 5B, C, E) but differs from them in having asymmetrical base. In having asymmetrical base our fossil shows resemblance with B. ovata where base varies from asymmetrical ([38], Plate 14, Figure 2) to symmetrical (CNH Herbarium sheet no. 400497). However, angle of divergence of secondary veins is more acute in B. ovata than that of our fossil. It appears that our fossil shows a combination of characters found in B. ovata, B. retusa and B. stipularis. The comparable species are distributed throughout the hotter parts of India, along the foot of the Himalaya, south India, Malacca, Malayan Peninsula, Myanmar, Sri Lanka, Philippines and tropical Africa [39].

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Figure 5. Bridelia leaves.

A. Enlarged apical portion of the fossil leaf showing craspedodromous and eucamptodromous venation (orange and blue arrows), secondary veins (yellow arrows) and percurrent tertiary veins (red arrows). B. Apical portion of the modern leaf of B. stipularis showing similar craspedodromous and eucamptodromous venation (orange and blue arrows) as found in the fossil and secondary veins (yellow arrows). C. Modern leaf of B. stipularis showing shape, size and venation pattern. D. Basal portion of the fossil leaf showing course of secondary veins (yellow arrows). E. Basal portion of the modern leaf of B. stipularis showing similar course of secondary veins as found in the fossil (yellow arrows).

https://doi.org/10.1371/journal.pone.0111140.g005

As far as fossil leaf records of Bridelia are concerned they are known mainly from Nepal and India. Two fossil species of the genus, namely B. mioretusa and B. siwalica are known from the Siwalik sediments (late Miocene) of Surai Khola, western Nepal [38]. Three more fossil species of Bridelia, namely B. stipularis and B. verucosa have been described from the Middle Siwalik sediments of Darjeeling, West Bengal [40], while another species viz., B. oligocenica is known from the late Oligocene sediments of Assam [15]. All the aforesaid fossils are different from the present fossil in a combination of characters (Table 1). Under such circumstances a new species, B. makumensis Srivastava and Mehrotra, sp. nov. is created and the specific epithet is after the fossil locality.

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Table 1. Comparative chart of the known fossil leaves of Bridelia from the Cenozoic sediments.

https://doi.org/10.1371/journal.pone.0111140.t001

Discussion

Fossil wood record of Bridelia

As far as the fossil records of Bridelia are concerned, they are known in the form of leaves and woods. The leaf fossil records have been discussed in the affinities (see section affinities). Fossil woods of Bridelia are known from various Tertiary sediments of central South Asia, temperate Asia, tropical Africa, Northern Africa, Europe, America and Australia [41] but their affinities with modern Bridelia are uncertain because of the homogeneity in wood characters of various genera of Euphorbiaceae s.l.

Bailey [42] instituted the genus Paraphyllanthoxylon for the fossil woods resembling Phyllanthoid Euphorbiaceae that includes the genus Bridelia also. However, he was not sure of its affinities. Wheeler et al. [43] after studying various species of Paraphyllanthoxylon concluded that the genus can not be assigned with certainty to the Euphorbiaceae because of its similarities to other families.

Ramanujam [44] instituted the genus Bischofioxylon for the fossil woods resembling Bischofia and described Bischofioxylon miocenicum from south India. Mädel [45] had suggested its affinities with Bridelia and merged it into another organ genus Bridelioxylon Mädel. Therefore, Bande [46] established Bischofinium for the fossil woods resembling Bischofia. Awasthi [47] suggested that neither B. miocenicum Ramanujam nor Biscofinium Bande belongs to Bischofia or Bridelia. The generic diagnosis of Bridelioxylon is within the range of generic diagnosis of Paraphyllanthoxylon Bailey. In our opinion due to the homogeneity in wood characters, it is difficult to separate Bridelia from other genera of the Euphorbiaceae.

Disjunct distribution pattern and possible migratory path of Bridelia from India to Africa-Madagascar and Southeast Asia

The disjunct phytogeography of Bridelia with equal distribution of species in Africa and tropical Asia and endemism in the African-Madagascar species are interesting. Based on the molecular data, Li et al. [8] inferred that Bridelia separated from its sister genus Cleistanthus at 33±5 Ma and suggested that the genus evolved in Southeast Asia and later migrated westward to India and Africa and eastward to Australia. However, this hypothesis didn’t get support from the fossil records of the genus. The present fossil record from the late Oligocene sediments of northeast India is important because during the late Oligocene, suturing of the Indian plate with the Eurasian plate was not complete to facilitate the plant migration between India and Southeast Asia (Figure 3) [11][13]. In the light of the oldest fossil evidence of Bridelia from northeast India we suggest that the genus evolved most likely during the late Oligocene in northeast India, while the speciation must have occurred during the Miocene followed by the dispersal of the genus from India to Southeast Asia via Myanmar as the suturing of both the aforesaid plates completed during the early Miocene [48], [49]. Our fossil shows affinity with three species of Bridelia, namely B. ovata, B. retusa and B. stipularis; this again suggests that the speciation must have occurred after the late Oligocene and most likely during the Miocene as suggested by the molecular data [8] and supported by the diversity in fossil records from the Siwalik of Nepal and India [38], [40]. The climatic conditions also favoured in the evolution of Bridelia because the late Oligocene was the time of last significant globally warm climate during the Cenozoic [50] under which the genus evolved and the speciation of the genus in Asia most likely to have occurred during the Middle Miocene Climatic Optimum (MMCO) [50]. All the above facts indicate that Bridelia evolved in India during the late Oligocene and after the complete suturing of Indian and Eurasian plates the genus migrated to Southeast Asia via Myanmar and then to Australia, along with several other plant taxa such as Alphonsea of the family Annonaceae [20], Mangifera [51] and Semecarpus of the family Anacardiaceae [18] (Figure 1). Similarly, the stem lineage of Bridelia also migrated to Africa via “Iranian Route” [52] during the late Miocene to early Pleistocene and this can be explained on the basis of plate tectonic model. Africa was isolated from Eurasia during the mid-Cretaceous to early Miocene [53]. By the early Miocene, Africa made land connections with east Eurasia via “Iranian Route” (Iranian and Arabian block) [52], and Bridelia most likely to have migrated through this route during the Miocene (Figure 1). After reaching to Africa, the stem lineage of the genus speciosed locally due to the availability of free niche and less competition which resulted in the local endemism of the genus in Africa. The speciation of stem lineage of Bridelia in Africa again coincides with the climatic condition in Africa i.e. occurrence of aridity in Africa during the late Neogene [54][56]. The aforesaid view also gets supports from the molecular phylogenetic study which suggests that the African clade speciosed at ca 3±1 Ma [8].

The corridor via “Iranian Route” was not only for Bridelia but also common for faunal exchange [52], [57] and several other African plant taxa reported from the Pliocene of western India [58]; this suggests that the migration was in between Africa and east Eurasia.

The migration of Bridelia from India to Africa and Southeast Asia again supports the “Out of India” hypothesis [59].

Palaeofloristics and Palaeoclimate of the Makum Coalfield, Assam

The Makum Coalfield is important in view of its high diversity of plant fossils. The late Oligocene was the time of last significant globally warm period during the Cenozoic and the fossil locality was situated at 10°–15° N palaeolatitude [10]. The known floristic diversity indicates that the family Fabaceae was the most dominant followed by Anacardiaceae, Clusiaceae, Combretaceae, Arecaceae, Annonaceae, Lauraceae and Sapindaceae etc. Most of the aforesaid families have pantropical distribution, while the abundance of palms indicates high water availability.

The families like Annonaceae, Burseraceae, Clusiaceae, Combretaceae, Lecythidaceae, Myristicaceae and Rhizophoraceae are typical pantropical megatherm families [60] whose presence in the palaeoflora provides an evidence that the CMT (mean temperature of the coldest month) was at least not less than 18°C [25]. Similarly, the presence of most dominant family Fabaceae [17] whose abundance and richness covary with the temperature [61], indicates warm climate. The occurrence of families Avicenniaceae and Rhizophoraceae is also very significant in terms of the depositional environment. These families are highly indicative of deltaic, mangrove or lacustrine deposition of coal seams and associated sediments in the Makum Coalfield [15]. The abundance of palms like Nypa [23] provides clear evidence of a coastal plain environment where both temperature and humidity remain high throughout the year [62]. Quantitative palaeoclimate reconstruction based on CLAMP analysis on the Makum Coalfield palaeoflora was made by Srivastava et al. [25]. They have used 80 different leaf morphotypes, from the Tirap colliery of the Makum Coalfield, which were analysed by following standard protocol of CLAMP analysis [63]. The CLAMP analysis indicates mean annual temperature (MAT) 28.3±3.7°C, warm month mean temperature (WMMT) 34.2±5.2°C and cold month mean temperature (CMMT) 23.6±5.5°C. The precipitation estimates suggest a marked seasonality in the rainfall pattern showing a wet season with 20 times the rainfall of the dry season. The similar pattern can be seen in Sunderbans lying in the modern Ganges/Brahmaputra/Meghna delta. Therefore, it is suggested that the South Asian Monsoon was already established by the late Oligocene time at an intensity similar to that of today [25].

Conclusions

Fossil evidences, along with the molecular data are important in studying the evolution and speciation of an organism. In the present paper we have reported fossil leaf of Bridelia from the late Oligocene sediments of northeast India and suggested its affinity with B. ovata, B. retusa and B. stipularis. Our fossil data, along with the known fossil records of Bridelia from the Neogene sediments of Nepal and India suggests that the genus evolved during the late Oligocene and migration and speciation occurred from India to Southeast Asia via Myanmar and from India to Africa via “Iranian Route” during the Miocene. The present finding fits well with the molecular phylogenetic analysis and plate tectonic models.

Acknowledgments

The authors are thankful to the authorities of the Coal India Limited (Northeastern Region), Margherita for permission to collect plant fossils from the Makum Coalfield. Thanks are also due to the Directors, Botanical Survey of India, Kolkata and the Forest Research Institute, Dehradun for permitting us to consult the herbarium. The authors are also thankful to Prof. Sunil Bajpai, Director, Birbal Sahni Institute of Palaeobotany, Lucknow for providing necessary facilities and permission to carry out this work. They are thankful to Prof. E.A. Wheeler of North Carolina State University, USA for sending her valuable reprints. The authors are also grateful to Prof. Khum Paudiyal, one anonymous reviewer and Prof. Navnith K.P. Kumaran for their valuable suggestions in improving the manuscript.

Author Contributions

Conceived and designed the experiments: GS RCM. Performed the experiments: GS RCM. Analyzed the data: GS RCM. Contributed reagents/materials/analysis tools: GS RCM. Contributed to the writing of the manuscript: GS RCM.

References

  1. 1. Stevens PF (2001 onwards). Angiosperm Phylogeny Website. Version 12, July 2012 [and more or less continuously updated since]. Available: http://www.mobot.org/MOBOT/research/APweb/. Accessed 2013 May 28.
  2. 2. APG II (2003) An update of the Angiosperm Phylogeny Group classification for the orders and families of flowering plants. APG II. Bot J Linn Soc 141: 399–436.
  3. 3. Muller J (1992) Fossil pollen records of extant angiosperms. Bot Rev 47: 1–142.
  4. 4. Gruas-Cavagnetto C, Köhler E (1992) Pollen fossils d’Euphorbiacées de l’Eocéne français. Grana 31: 291–304.
  5. 5. Dressler S (1996) The genus Bridelia Willd. (Euphorbiaceae) in Malesia and Indochina: a regional revision. Blumea 41: 263–331.
  6. 6. Forster PI (1999) A taxonomic revision of Bridelia Willd. (Euphorbiaceae) in Australia. Austrobaileya 5: 405–419.
  7. 7. Li PT, Dressler S (2008) Euphorbiaceae. In: Wu ZY, Raven PH, Hong DY, eds. Flora of China. Beijing, China: Science Press/St Louis: Miss Bot Garden Press. pp. 172–177.
  8. 8. Li Yongquan, Dressler S, Zhang D, Renner SS (2009) More Miocene dispersal between Africa and Asia- the case of Bridelia (Phyllanthaceae). Syst Bot 34(3): 521–529.
  9. 9. Gradstein FM, Ogg JG, Smith A (2004) A Geologic Time Scale. Cambridge, UK: Cambridge University Press.
  10. 10. Molnar P, Stock JM (2009) Slowing of India’s convergence with Eurasia since 20 Ma and its implications for Tibetan mantle dynamics. Tectonics 28: TC3002.
  11. 11. Lakhanpal RN (1970) Tertiary flora of India and their bearing on the historical geology of the region. Taxon 19: 675–694.
  12. 12. Bande MB, Prakash U (1986) The Tertiary flora of Southeast Asia with remarks on its palaeoenvironment and phytogeography of the Indo-Malayan region. Rev Palaeobot Palynol 49: 203–233.
  13. 13. Srivastava G, Mehrotra RC (2010) Tertiary flora of northeast India vis-á-vis movement of the Indian plate. Mem Geol Soc India 75: 123–130.
  14. 14. Awasthi N, Mehrotra RC, Lakhanpal RN (1992) Occurrence of Podocarpus and Mesua in the Oligocene sediments of Makum Coalfield, Assam, India. Geophytology 22: 193–198.
  15. 15. Awasthi N, Mehrotra RC (1995) Oligocene flora from Makum Coalfield, Assam, India. Palaeobotanist 44: 157–188.
  16. 16. Mehrotra RC, Dilcher DL, Lott TA (2009) Notes on elements of the Oligocene flora from the Makum Coalfield, Assam, India. Palaeobotanist 58: 1–9.
  17. 17. Srivastava G, Mehrotra RC (2010) New legume fruits from the Oligocene sediments of Assam. J Geol Soc India 75: 820–828.
  18. 18. Srivastava G, Mehrotra RC (2012) Oldest fossil of Semecarpus L.f. from the Makum Coalfield, Assam, India and comments on its origin. Curr Sci 102(3): 398–400.
  19. 19. Srivastava G, Mehrotra RC, Bauer H (2012) Palm leaves from the Late Oligocene sediments of Makum Coalfield, Assam. J Earth Syst Sci 121(3): 747–754.
  20. 20. Srivastava G, Mehrotra RC (2013) First fossil record of Alphonsea Hk. f. & T. (Annonaceae) from the late Oligocene sediments of Assam, India and comments on its phytogeography. PLoS ONE 8(1): e53177.
  21. 21. Srivastava G, Mehrotra RC (2013) Endemism due to climate change: evidence from Poeciloneuron Bedd. (Clusiaceae) leaf fossil from Assam, India. J Earth Syst Sci 122(2): 283–288.
  22. 22. Srivastava G, Mehrotra RC (2013) Further contribution to the low latitude leaf assemblage from the late Oligocene sediments of Assam and its phytogeographical significance. J Earth Syst Sci 122(5): 1341–1357.
  23. 23. Mehrotra RC, Tiwari RP, Mazumber BI (2003) Nypa megafossils from the Tertiary sediments of northeast India. Geobios 36: 83–92.
  24. 24. Kumar M, Srivastava G, Spicer RA, Spicer TEV, Mehrotra RC, et al. (2012) Sedimentology, palynostratigraphy and palynofacies of the late Oligocene Makum Coalfield, Assam, India: a window on lowland tropical vegetation during the most recent episode of significant global warmth. Palaeogeogr Palaeoclimatol Palaeoecol 342–343: 143–162.
  25. 25. Srivastava G, Spicer RA, Spicer TEV, Yang J, Kumar M, et al. (2012) Megaflora and palaeoclimate of a late Oligocene tropical delta, Makum Coalfield, Assam: evidence for the early development of the South Asia monsoon. Palaeogeogr Palaeoclimatol Palaeoecol 342–343: 130–142.
  26. 26. Pascoe EH (1964) A Manual of the Geology of India and Burma. Calcutta: Geol Surv India.
  27. 27. Ganju JI, Khare BM, Chaturvedi JS (1986) Geology and hydrocarbon prospects of Naga Hills south of 27° latitude. Bull Oil Nat Gas Comm 23: 129–145.
  28. 28. Misra BK (1992) Tertiary coals of Makum Coalfield, Assam, India; petrography, genesis and sedimentation. Palaeobotanist 39(3): 309–326.
  29. 29. Mishra HK, Ghosh RK (1996) Geology, petrology and utilization of some Tertiary coals of the northeastern region of India. Int J Coal Geol 30: 65–100.
  30. 30. Hickey LJ (1973) Classification of the architecture of dicotyledonous leaves. Am J Bot 60: 17–33.
  31. 31. Dilcher DL (1974) Approaches to the identification of angiosperm leaf remains. Bot Rev 40: 1–157.
  32. 32. Ellis B, Daly DC, Hickey LJ, Johnson KR, Mitchell JD, et al.. (2009) Manual of leaf architecture. USA: Cornell University Press.
  33. 33. Jussieu ALD (1820) O Prirozenosti Rostin 225.
  34. 34. Martinov II (1820) Tekhno-Botanicheskīi˘ Slovar’: na latinskom i rossīi˘skom ăzykakh. Sanktpeterburgie: V tip. Imperatorskoi˘ rossīi˘skoi˘ akademīi.
  35. 35. Ascherson PFA (1864) Flora der Provinz Brandenburg. 1(2): 59.
  36. 36. Müller Argoviensis J (1864) Botanische Zeitung. 22: 324.
  37. 37. Willdenow CLv (1806) Species Plantarum. Berlin: Editio Quarta 4.
  38. 38. Prasad M, Pandey SM (2008) Plant diversity and climate during Siwalik (Miocene-Pliocene) in the Himalayan foot-hills of western Nepal. Palaeontographica B 278: 13–70.
  39. 39. Hooker JD (1885) The flora of British India 5. Kent: Reeve & Company.
  40. 40. Pathak NR (1969) Megafossils from the foot-hills of Darjeeling District, India. In: Santapau H, et al.., eds. J Sen Memorial volume. Calcutta, India: Bot Soc of Bengal. pp. 379–384.
  41. 41. Gregory M, Poole I, Wheeler EA (2009) Fossil dicot wood names: an annotated list with full bibliography. IAWA (suppl 6): 220.
  42. 42. Bailey IW (1924) The problem of identifying the wood of Cretaceous and later dicotyledons: Paraphyllanthoxylon arizonense. Ann Bot 38: 439–451.
  43. 43. Wheeler EA, Lee M, Matten LC (1987) Dicotyledonous woods from the Upper Cretaceous of southern Illinois. Bot J Linn Soc 94: 111–126.
  44. 44. Ramanujam CGK (1960) Silicified woods from the Tertiary rocks of South India. Palaeontographica B 106: 99–140.
  45. 45. Mädel E (1962) Die fossilen Euphorbiaceen-Hölzer mit besonderer Berücksichtigung neuer Funde aus der Oberkreide Süd-Afrikas. Senckenberg. Lethaea 43: 283–321.
  46. 46. Bande MB (1974) Two fossil woods from the Deccan Intertrappean beds of Mandla District, Madhya Pradesh. Geophytology 4(2): 189–195.
  47. 47. Awasthi N (1989) Occurrence of Bischofia and Antiaris in Namsang beds (Miocene-Pliocene) near Deomali, Arunachal Pradesh, with remarks on the identification of fossil woods referred to Bischofia. Palaeobotanist 37: 147–151.
  48. 48. Chatterjee S, Scotese CR (1999) The breakup of Gondwana and the evolution and biogeography of the Indian plate. Proc Indian Natl Sci Acad A 65: 397–425.
  49. 49. Chatterjee S, Goswami A, Scotese CR (2013) The longest voyage: tectonic, magmatic, and paleoclimatic evolution of the Indian plate during its northward flight from Gondwana to Asia. Gond Res 23: 238–267.
  50. 50. Zachos J, Pagani M, Sloan L, Thomas E, Billups K (2001) Trends, rhythms, and aberrations in global climate 65 Ma to present. Science 292: 686–693.
  51. 51. Mehrotra RC, Dilcher DL, Awasthi N (1998) A Palaeocene Mangifera- like leaf fossil from India. Phytomorphology 48: 91–100.
  52. 52. Gheerbrant E, Rage J-C (2006) Paleobiogeography of Africa: how distinct from Gondwana and Laurasia? Palaeogeogr Palaeoclimatol Palaeoecol 241: 224–246.
  53. 53. McLoughlin S (2001) The breakup history of Gondwana and its impact on pre-Cenozoic floristic provincialism. Aust J Bot 49: 271–300.
  54. 54. Griffin David L (2002) Aridity and humidity: two aspects of the late Miocene climate of North Africa and the Mediterranean. Palaeogeogr Palaeoclimatol Palaeoecol 182: 65–91.
  55. 55. Bobe R (2006) The evolution of arid ecosystem in eastern Africa. J Arid Environ 66: 564–584.
  56. 56. Bonnefille R (2010) Cenozoic vegetation, climate changes and hominid evolution in tropical Africa. Global Planet Change 72: 390–411.
  57. 57. Bibi F (2011) Mio-Pliocene faunal exchanges and African biogeography: the record of fossil bovids. PLoS ONE 6(2): e16688.
  58. 58. Shukla A, Mehrotra RC, Guleria JS (2012) African elements (fossil woods) from the upper Cenozoic sediments of western India and their palaeoecological and phytogeographical significance. Alcheringa 37(1): 1–18.
  59. 59. Bossuyt F, Milinkovitch MC (2001) Amphibians as indicators of early Tertiary “Out-of-India” dispersal of vertebrates. Science 292: 93–95.
  60. 60. van Steenis CGGJ (1962) The land bridge theory in Botany. Blumea 11: 235–372.
  61. 61. Punyasena SW, Eshel G, McElwain JC (2008) The influence of climate on the spatial patterning of neotropical plant families. J Biogeogr 35: 117–130.
  62. 62. Tomlinson PB (1990) The Structural Biology of Palms. Oxford, UK: Clarendon Press.
  63. 63. Wolfe JA (1993) A method of obtaining climatic parameters from leaf assemblages. U S Geol Surv Bull 2040: 1–73.
  64. 64. Global Biodiversity Information Facility Website. Available: http://data.gbif.org/species/3076094/. Accessed 2013 May 28.
  65. 65. Ahmed M (1996) Petrology of Oligocene coal, Makum coalfield, Assam, northeast India. Int J Coal Geol 30: 319–325.
  66. 66. Colorado Plateau Geosystems, Inc. Available: http://cpgeosystems.com/paleomaps.html. Accessed 2013 May 28.