T

T. H. Morgan

Borges, R.M. (2009).
Revolutions in evolutionary thought: Darwin and after.
Resonance 14:102–123.

Borges, R.M. (2005).
Ernst Mayr and evolutionary biology: polemics and synthesis.
Current Science 89:947–954.

Borges, R.M. (2005).
Polemics and synthesis: Ernst Mayr and evolutionary biology.
Resonance 10:21–33.

Tangled Bank

Borges, R.M. (1998).
Clonal versus sexual fish–who wins?
Journal of Biosciences 23:166-167.

Technomyrmex albipes

Shenoy, M., Radhika, V., Satish, S., Borges, R.M. (2012).
Composition of extrafloral nectar influences interactions between the myrmecophyte Humboldtia brunonis and its ant associates.
Journal of Chemical Ecology 38:88–99.

Ghara, M., Kundanati, L., Borges, R.M. (2011).
Nature’s Swiss army knives: ovipositor structure mirrors ecology in a multitrophic fig wasp community.
PLOS One 6:e23642.

Ranganathan, Y., Ghara, M., Borges, R.M. (2010).
Temporal association in fig–wasp–ant interactions: diel and phenological patterns.
Entomologia Experimentalis et Applicata 137:50–61.

Shenoy, M., Borges, R.M. (2010).
Geographical variation in an ant–plant interaction correlates with domatia occupancy, local ant diversity and interlopers.
Biological Journal of the Linnean Society 100:538–551.

Ranganathan, Y., Borges, R.M. (2009).
Predatory and trophobiont-tending ants respond differently to fig and fig wasp volatiles.
Animal Behaviour 77:1539–1545.

Gaume, L., Shenoy, M., Zacharias, M., Borges, R.M. (2006).
Co-existence of ants and an arboreal earthworm in a myrmecophyte of the Indian Western Ghats: anti-predation effect of the earthworm mucus.
Journal of Tropical Ecology 22:1–4.

Gaume, L., Zacharias, M., Grosbois, V., Borges, R.M. (2005).
The fitness consequences of bearing domatia and having the right ant partner: experiments with protective and non-protective ants in a semi-myrmecophyte.
Oecologia 145:76–86.

Gaume, L., Zacharias, M., Borges, R. M. (2005).
Ant–plant conflicts and a novel case of castration parasitism in a myrmecophyte.
Evolutionary Ecology Research 7:435–452.

Temperature

Borges, R.M. (2018).
Dark matters: challenges of nocturnal communication between plants and animals in delivery of pollination services.
Yale Journal of Biology and Medicine 91: 33–42.

Katariya, L., Ramesh, P.B., Borges, R.M. (2017).
Dynamic environments of fungus‐farming termite mounds exert growth‐modulating effects on fungal crop parasites.
Environmental Microbiology.

Borges, R.M., Somanathan, H., Kelber, A. (2016).
Patterns and processes in nocturnal and crepuscular pollination.
Quarterly Review of Biology 91:389–418.

Krishnan, A., Pramanik, G. K., Revadi, S. V., Venkateswaran, V., Borges, R.M. (2014).
High temperatures result in smaller nurseries which lower reproduction of pollinators and parasites in a brood site pollination mutualism.
PLOS ONE 9: e115118.

Somanathan, H., Borges, R. M. (2001).
Nocturnal pollination by the carpenter bee Xylocopa tenuiscapa (Apidae) and the effect of floral display on fruit set of Heterophragma quadriloculare (Bignoniaceae) in India.
Biotropica 33:78–89.

Borges, R.M. (2000).
Feverish honeybees.
Journal of Biosciences 25:215–216.

Teratodiplogaster

Gupta, S., Borges, R.M. (2019).
Density‐dependent fitness effects stabilize parasitic hitchhiking within a mutualism.
Functional Ecology 33:2304–2315.

Termite castes

Zachariah, N., Singh, S., Murthy, T.G., Borges, R.M. (2020).
Bi-layered architecture facilitates high strength and ventilation in nest mounds of fungus-farming termites.
Scientific Reports.

Zachariah, N., Murthy, T.G., Borges, R.M. (2020).
Moisture alone is sufficient to impart strength but not weathering resistance to termite mound soil.
Royal Society Open Science 7:200485.

Katariya, L., Ramesh, P.B., Sharma, A., Borges, R.M. (2018).
Local hypoxia generated by live burial is effective in weed control in termite fungus farms.
Insectes Sociaux 65:561–569.

Katariya, L., Ramesh, P.B., Gopalappa, T., Desireddy, S., Bessière, J.-M., Borges, R.M. (2017).
Fungus-farming termites selectively bury weedy fungi that smell different from crop fungi.
Journal of Chemical Ecology 43:986–995.

Zachariah, N., Das, A., Murthy, T.G., Borges, R.M. (2017).
Building mud castles: perspectives from brick-laying termites.
Scientific Reports (Nature).

Termite mound

Zachariah, N., Singh, S., Murthy, T.G., Borges, R.M. (2020).
Bi-layered architecture facilitates high strength and ventilation in nest mounds of fungus-farming termites.
Scientific Reports.

Zachariah, N., Murthy, T.G., Borges, R.M. (2020).
Moisture alone is sufficient to impart strength but not weathering resistance to termite mound soil.
Royal Society Open Science 7:200485.

Katariya, L., Ramesh, P.B., Gopalappa, T., Desireddy, S., Bessière, J.-M., Borges, R.M. (2017).
Fungus-farming termites selectively bury weedy fungi that smell different from crop fungi.
Journal of Chemical Ecology 43:986–995.

Katariya, L., Ramesh, P.B., Borges, R.M. (2017).
Dynamic environments of fungus‐farming termite mounds exert growth‐modulating effects on fungal crop parasites.
Environmental Microbiology.

Zachariah, N., Das, A., Murthy, T.G., Borges, R.M. (2017).
Building mud castles: perspectives from brick-laying termites.
Scientific Reports (Nature).

Katariya, L., Ramesh, P.B., Gopalappa, T., Borges, R.M. (2017).
Sex and diversity: the mutualistic and parasitic fungi of a fungus-growing termite differ in genetic diversity and reproductive strategy.
Fungal Ecology 26:20–27.

Kandasami, R.K., Borges, R.M., Murthy, T.G. (2016).
Effect of biocementation on the strength and stability of termite mounds.
Environmental Geotechnics 3:99–113.

Termite secretions

Zachariah, N., Murthy, T.G., Borges, R.M. (2020).
Moisture alone is sufficient to impart strength but not weathering resistance to termite mound soil.
Royal Society Open Science 7:200485.

Termitomyces

Katariya, L., Ramesh, P.B., Sharma, A., Borges, R.M. (2018).
Local hypoxia generated by live burial is effective in weed control in termite fungus farms.
Insectes Sociaux 65:561–569.

Katariya, L., Ramesh, P.B., Gopalappa, T., Desireddy, S., Bessière, J.-M., Borges, R.M. (2017).
Fungus-farming termites selectively bury weedy fungi that smell different from crop fungi.
Journal of Chemical Ecology 43:986–995.

Katariya, L., Ramesh, P.B., Borges, R.M. (2017).
Dynamic environments of fungus‐farming termite mounds exert growth‐modulating effects on fungal crop parasites.
Environmental Microbiology.

Katariya, L., Ramesh, P.B., Gopalappa, T., Borges, R.M. (2017).
Sex and diversity: the mutualistic and parasitic fungi of a fungus-growing termite differ in genetic diversity and reproductive strategy.
Fungal Ecology 26:20–27.

Theoretical Ecology

Venkateshwaran, V. & Borges, R.M. (2021).
Staying in the club: Exploring criteria governing metacommunity membership for obligate symbionts under host–symbiont feedback.
Journal of Theoretical Biology. 510:110512.

Prasad, B.R.G., Borges, R.M. (2006).
Searching on patch networks using correlated random walks: Space usage and optimal foraging predictions using Markov chain models.
Journal of Theoretical Biology 240:241–249.

Thermoregulation

Borges, R.M. (2000).
Feverish honeybees.
Journal of Biosciences 25:215–216.

Thomas Henry Huxley

Borges, R.M. (2009).
Revolutions in evolutionary thought: Darwin and after.
Resonance 14:102–123.

Borges, R.M. (1998).
Leviathan, natural selection, and ethics.
Current Science 74:750–758.

Borges, R.M. (1997).
Ethics and evolution: Thomas Henry Huxley and the problem of evil.
Pages 61–66 In: Proceedings of the National Seminar on Bioethics. Indian Perspectives. Organised by the Indian Council of Philosophical Research and the Department of Philosophy, Goa University.

Thomas Hobbes

Borges, R.M. (1998).
Leviathan, natural selection, and ethics.
Current Science 74:750–758.

Tramp ant

Gaume, L., Zacharias, M., Grosbois, V., Borges, R.M. (2005).
The fitness consequences of bearing domatia and having the right ant partner: experiments with protective and non-protective ants in a semi-myrmecophyte.
Oecologia 145:76–86.

Tripartite interaction

Katariya, L., Ramesh, P.B., Gopalappa, T., Borges, R.M. (2017).
Sex and diversity: the mutualistic and parasitic fungi of a fungus-growing termite differ in genetic diversity and reproductive strategy.
Fungal Ecology 26:20–27.

Tritrophic interactions

Krishnan, A., Ghara, M., Kasinathan, S., Pramanik, G. K., Revadi, S., Borges, R. M. (2015).
Plant reproductive traits mediate tritrophic feedback effects within an obligate brood-site pollination mutualism.
Oecologia 179:797–809.

Krishnan, A., Muralidharan, S., Sharma, L., Borges, R.M. (2010).
A hitchhiker’s guide to a crowded syconium: how do fig nematodes find the right ride?
Functional Ecology 24:741–749.

Trophic interaction

Borges, R.M. (2021).
Interactions between figs and gall-inducing fig wasps: adaptations, constraints and unanswered questions.
Frontiers in Ecology and Evolution 9:685542.

Borges, R.M. (2018).
The galling truth: limited knowledge of gall-associated volatiles in multitrophic interactions.
Frontiers in Plant Science 9:1130.

Krishnan, A., Ghara, M., Kasinathan, S., Pramanik, G. K., Revadi, S., Borges, R. M. (2015).
Plant reproductive traits mediate tritrophic feedback effects within an obligate brood-site pollination mutualism.
Oecologia 179:797–809.

Chanam, J., Sheshshayee, M.S., Kasinathan, S., Jagdeesh, A., Joshi, K.A., Borges, R.M. (2014).
Nutritional benefits from domatia inhabitants in an ant–plant interaction: interlopers do pay the rent.
Functional Ecology 28:1107–1116 [Paper was featured in New Scientist].

Krishnan, A., Muralidharan, S., Sharma, L., Borges, R.M. (2010).
A hitchhiker’s guide to a crowded syconium: how do fig nematodes find the right ride?
Functional Ecology 24:741–749.

Trophic mutualism

Chanam, J., Kasinathan, S., Pramanik, G.K., Jagdeesh, A., Joshi, K.A., Borges, R.M. (2015).
Foliar extrafloral nectar of Humboldtia brunonis (Fabaceae), a paleotropical ant-plant, is richer than phloem sap and more attractive than honeydew.
Biotropica 47:1–5.