Paper published in PNAS

A new paper published in PNAS this week provides evidence for chloroplast pyrenoid formation in the green alga Chlamydamonas. The pyrenoid, once thought to be a starch-storage granule, is now recognized to be the centre of a carbon concentrating mechanism which turbocharges photosynthesis.

Moritz Meyer, Maddie Mitchell and Howard Griffiths, in collaboration with colleagues in UNL Nebraska, have shown that modifications to the primary carboxylase, Rubisco, are responsible for pyrenoid formation. Specifically, it seems that two regions of the small subunit, the alpha helices, interact to allow Rubisco to aggregate into the pyrenoid, which also regulates CCM activity.

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Blowing in the wind: how hidden flower features are crucial for bees

New research reveals that velcro-like cells on plant petals play a crucial role in helping bees grip flowers.

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Katrina Alcorn, Heather Whitney and Beverley Glover (2012). 'Flower movement increases pollinator preference for flowers with better grip', doi: 10.1111/j.1365-2435.2012.02009.x is published in Functional Ecology on Tuesday 29 May 2012.

Seed size is controlled by maternally produced small RNAs, scientists find

Z. Jeff Chen, the D.J. Sibley Centennial Professor in Plant Molecular Genetics at The University of Texas at Austin and his colleagues, including David Baulcombe at the University of Cambridge, provide the first genetic evidence that seed development is controlled by maternally inherited "small interfering RNAs," or siRNAs.

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Extraordinary transgressive phenotypes of hybrid tomato are influenced by epigenetics and small silencing RNAs

New research from Dr Shivaprasad in the Baulcombe group explains why hybrid plants are sometimes much more vigorous or much weaker than the parents. Their findings that have been published recently in the EMBO Journal (http://dx.doi.org/10.1038/emboj.2011.458) will influence thinking about evolutionary mechanisms and the use of hybrid plants in agriculture.

Scientists discover why buttercups reflect yellow on chins – and it doesn’t have anything to do with whether you like butter

New research sheds light on children's game and provides insight into pollination

Scientists have found that the distinctive glossiness of the buttercup flower (Ranunculus repens), which children like to shine under the chin to test whether their friends like butter, is related to its unique anatomical structure. Their findings were published today, 14 December, in the Royal Society journal Interface.

The researchers discovered that the buttercup petal's unique bright and glossy appearance is the result of the interplay between its different layers. In particular, the strong yellow reflection responsible for the chin illumination is mainly due to the epidermal layer of the petal that reflects yellow light with an intensity that is comparable to glass.

Scientists have been interested in how the buttercup flower works for over a century. They have previously shown that the reflected colour is yellow due to the absorption of the colours in the blue-green region of the spectrum by the carotenoid pigment in the petals. As the blue-green light is absorbed, the light in the other spectral regions (in this case, primarily yellow) is reflected. It has also been known for many years that the epidermal layer of the petals is composed of very flat cells, providing strong reflection.

This new study shows how the buttercup's exceptionally bright appearance is a result of a special feature of the petal structure. The epidermal layer of cells has not one but two extremely flat surfaces from which light is reflected. One is the top of the cells, the other exists because the epidermis is separated from the lower layers of the petal by an air gap. Reflection of light by the smooth surface of the cells and by the air layer effectively doubles the gloss of the petal, explaining why buttercups are so much better at reflecting light under your chin than any other flower.

The researchers also found that the buttercup reflects a significant amount of UV light. As many pollinators, including bees, have eyes sensitive in the UV region, this provides insight into how the buttercup uses its unique appearance to attract insects.

Dr Silvia Vignolini, from the University of Cambridge’s Department of Physics (Cavendish Laboratory), explained the importance of the buttercup’s unique appearance: "Although many different factors, such as scent and temperature, influence the relationships between pollinators and flowers, the visual appearance of flowers is one of the most important factors in this communication. Flowers develop brilliant colour, or additional cues, such as glossiness - in the case of the buttercup - that contribute to make the optical response of the flower unique. Moreover, the glossiness might also mimic the presence of nectar droplets on the petals, making them that much more attractive."

Dr Beverley Glover, Department of Plant Sciences, said: "This phenomenon has intrigued scientists and laymen alike for centuries. Our research provides exciting insight into not only a children’s game but also into the lengths to which flowers will go to attract pollinators."

Professor Ulli Steiner, from the Nanophotonics Centre at the Cavendish Laboratory, the University of Cambridge’s Department of Physics, said: "It is fun to revisit a problem that is more than one century old and, using modern methods, discover something new. The strong collaboration between Physics and the Plant Sciences has enabled this."


The paper ‘Directional scattering from the glossy flower of Ranunculus: how the buttercup lights up your chin’ will be published in the 14 December edition of the Royal Society journal Interface.

A new type of signal molecule in plants discovered

Attila Molnar, Charles Melnyk and colleagues in the Baulcombe group have discovered a new type of signal molecule in plants. In a paper published online in Science (23/4/2010) they show that small RNA molecules, known as small interfering RNAs, can migrate long distances in plants and they can direct chemical modification of DNA in the recipient cells. This modification – DNA methylation – normally results in the silencing of gene expression that persists through cell divisions even if the mobile RNA is no longer present. The newly discovered signal could explain many mysterious phenomena in plant biology in which a local stimulus induces a long term and persistent effect in the recipient tissues.

"Small silencing RNAs in plants are mobile and they direct epigenetic modification in recipient cells"

Attila Molnar*, Charles W. Melnyk*, Andrew Bassett, Thomas J. Hardcastle, Ruth Dunn, David C. Baulcombe

The abstract and full text of the paper can be downloaded from
http://www.plantsci.cam.ac.uk/research/baulcombe/publications.html.

Image: Silencing of the GFP reporter gene in Arabidopsis roots by mobile small RNAs derived from GFP silenced shoots. Imaged using UV fluorescence, the green colour indicates non-silenced GFP fluorescing roots and red indicates silenced auto-fluorescencing tissue.

Maternal influence through small RNA

Just as the universe is filled with mysterious and unexplained matter, so living cells are filled with small RNAs – the “dark matter” of genetics. Plants cells contain hundreds of thousands of these tiny molecules but only for a few of them is there a known function. Cambridge University scientists recently discovered a surprising characteristic of small RNAs in plants. In an article published online today in the journal Nature, researchers led by Professor David Baulcombe describe maternal-specific expression of the most abundant class of small RNAs in developing seeds. Although the small RNAs are produced from cells containing genes from both parents, only the maternal genes are active. Scientists have known for decades that organisms have a molecular memory of which genes they have inherited from each parent and this “imprint” is of critical importance in a number of human diseases. However, very little is known about the nature of imprinting or why such a mechanism would evolve. Dr. Rebecca Mosher, a senior researcher in the group, suggests that imprinted expression of small RNAs indicates large-scale genetic control by the mother – perhaps an evolutionary example of over-parenting.

Read the publication in Nature


A developing seed contains two cell types with maternal DNA – the endosperm (green area) and the embryo (brown). The maternal (purple edge) and paternal (brown) genomes are both active but only the maternal genomes generate small RNA (purple line).

Five crop researchers who could change the world

Julian Hibberd has been identified as one of 'Five crop researchers who could change the world' by Nature, the top interdisciplinary scientific journal (volume 456, 563-569). The Nature news feature covers the work of five ambitious scientists determined to stop the world from going hungry. Julian's research programme, with funding from the International Rice Research Institute, will attempt to produce rice with the C4 photosynthesis pathway, potentially increasing grain yield by up to 50%.

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