Full list of my publications


14. Afify A, Betz JF, Riabinina O, Potter CJ. Commonly used insect repellents hide human odors from Anopheles mosquitoes. link

13. Langridge KV, Wilke C, Riabinina O, Vorobyev M, Hempel de Ibarra N. Approach direction prior to landing explains patterns of colour learning in bees. link 

Peer-reviewed publications:

12. Riabinina O, Vernon SW, Dickson BJ, Baines RA. (2019) Split-QF system for fine-tuned transgene expression in Drosophila. Genetics, 212, 1, 53-63. link

Here we introduced the two forms of split-QF, with QF2 and QF2w activation domains, into Drosophila. We quantified the strength of full and split QF transactivators in larvae and adult flies by luciferase assay. We demonstrated that split-QF is fully functional, repressible by QS and inducible by Quinic Acid (QA), just like the original QF2/2w transactivators. QFAD activation domain also works well with GAL4DBD and LexADBD DNA-binding domains, making them QS-repressible and QA inducible. Finally, we demonstrate the use of split-QF in intersectional labelling experiments, single-cell electrophysiology, optogenetic and thermogenetic behavioural experiments.

11. Riabinina O, Task D, Marr E, Lin C-C, Alford R, O’Brochta DA, Potter CJ.  (2016) Organisation of olfactory centers in the malaria mosquito Anopheles gambiae. Nature Communications, 7, 13010. link     pdf    suppl data and 3D models

This paper is important for three reasons. First, we introduced the Q-system into malaria mosquito, and demonstrated that it drives strong expression which is not silenced or otherwise affected over 10+ generations of mosquitoes. Second, we generated the first ever mosquito with genetically labelled neurons, thus advancing the neurogenetics of mosquitoes to the next level. Third, we describe here the anatomy of Orco+ olfactory receptor neurons of A. gambiae, that project not only to the antennal lobe as expected, but also to the SEZ – the area of the brain that in flies receives gustatory inputs. This neuronal organisation suggest possible early integration of taste and smell signals.

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10. Lin C-C, Riabinina O, Potter CJ. (2016) Olfactory behaviors assayed by computer tracking of Drosophila in a four-quadrant olfactometer. Journal of Visualzed Experiments, 114, e54346, doi:10.3791/54346. link pdf

This video article shows and describes in detail the 4-quadrant setup that we used extensively for behavioural experiments on Drosophila. Sadly, I don’t appear in the video because I had moved back to the UK before the video was recorded in our lab at Hopkins!

9. Gao XJ, Riabinina O, Potter CJ, Clandinin TR, Luo L. (2015) A Transcriptional Reporter of Intracellular Ca2+ in Drosophila. Nature Neuroscience, 18, 917-925. link  pdf

This paper presents a new method for activity-dependent neuronal labelling. TRIC is designed to report slow changes in neuronal activity, and may be used to functionally manipulate active cells.

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8. Riabinina O, Luginbuhl D, Marr E, Liu S, Wu MN, Luo L, Potter CJ. (2015) Improved and expanded Q-system reagents for genetic manipulations. Nature Methods, 12, 219-222  link  pdf

This paper presents a major tour de force in development of the Q-system for transgene expression. The second generation of the transactivator QF, called QF2, doesn’t suffer from toxicity and can drive broad and strong expression without having adverse health effects in flies. We demonstrate its use for pan-neuronal and ubiquitous expression of fluorescent reporters in larvae and adult flies. We also describe novel chimeric transactivators, GAL4QF and LexAQF, that allow for advanced genetic manipulations.

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7. Riabinina O, Hempel de Ibarra N, Philippides AO, Collett TS. (2014) Head movements and the optic flow generated during the learning flights of bumblebees. Journal of Experimental Biology, 217, 2633-2642 link  pdf video abstract

This is the last paper out of four that describe orientation flight in bumblebees. Here we used high-speed video recordings to determine how the bees move during the first several seconds after leaving their nest. We discovered that bumblebees use a modified version of “saccade-and-fixate” strategy with imperfect fixations, that helps them to estimate the distance between landmarks and the nest (see the video abstract below for more details!)

6. Philippides AO, Hempel de Ibarra N, Riabinina O, Collett TS. (2013) Bumblebee calligraphy: the design and control of flight motifs in the learning and return flights of Bombus terrestris. Journal of Experimental Biology, 216, 1093-1104 link  pdf

This paper describes the two structural elements of the bumblebees’ learning flights, loops and zigzags, that bear many functional similarities. We show that loops allow the bees to face their nest while flying around it and presumably collecting visual information about the position of the nest relative to nearby landmarks. Zigzags are used predominantly during returns flights.

A bumblebee is exploring a landmark

5. Collett TS, Hempel de Ibarra N, Riabinina O, Philippides AO. (2013) Coordinating compass-based and nest-based flight directions during bumblebee learning and return flights. Journal of Experimental Biology, 216, 1105-1113 link  pdf

Here we describe how the nest-centered loops and zigzags of bees’ orientation flights are oriented relative to the compass directions.

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4. Riabinina O*, Hempel de Ibarra N*, Howard L, Collett TS (2011) Do wood ants learn sequences of visual stimuli? Journal of Experimental Biology, 214, 2739-2748 link  pdf

Wood ants use visual cues to get back to their nest after a foraging trip. But how do they link numerous views that they encounter during their trip, and how do they know the correct order of these views? Here, we trained the ants to remember a sequence of visual patterns – a task that the ants found very difficult indeed!

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3. Riabinina O, Dai M, Duke T, Albert JT (2011) Active process mediates species-specific tuning of Drosophila ears. Current Biology, 21, 658–664 link pdf

This paper describes an interesting finding that ear tuning of various Drosophila species is in good agreement with the spectral content of the courtship songs of these species.

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2. Hempel de Ibarra N, Philippides AO, Riabinina O, Collett TS (2009) Preferred viewing directions of bumblebees (Bombus terrestris L.) when learning and approaching their nest site. Journal of Experimental Biology, 212, 3193-3204 link  pdf

This paper was the first in the series of four that present our attempt to understand how bumblebees acquire visual information about the surroundings of their nest. We show here that the bees are trying to view dark objects against a bright background, and possibly make use of the olfactory cues, brought by the gusts of wind.

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1. Riabinina O, Philippides AO (2009) A model of visual detection of angular speed for bees. Journal of Theoretical Biology, 257, 61–72 link  pdf

This paper proposes a simple design for an angular speed detector that could underlie the centering response, observed in honeybees flying in a narrow tunnel. The design is based on the modified Hassenstein and Reichardt detector of temporal frequency, which was used to explain the optomotor response in insects.


Book chapters:

1. Riabinina O, Potter CJ. The Q-system: A versatile Expression System for Drosophila. In Drosophila: Methods and Protocols (ed: C. Dahmann) (Methods in Molecular Biology, Vol. 1478, 53-78) link  pdf  purchase from Amazon

A review chapter on the Q-system, including the second generation of the Q-system, the chimeric transactivators, logic gates and MARCM.

Qbook MAX_C1-221214_act-GAL4QF_UAS-mdtd_syb-QF2w_QUAS-mcd8::GFP_eyedisc1.lsm_RGB MAX_C2-011214_Orco-G4_UAS-mcd8-GFP_GH146-QF_QUAS-mtdt_1.lsm_RGB_edited