Tag: reproduction

fungal sex

penicillium

Penicillium chrysogenum bacteria

Penicillium bacteria were thought to reproduce asexually. A new study shows that a certain strain of the bacteria still has the genes required to carry out sexual reproduction and that these genes are linked to the production of penicillin. From SciAm:

Paul Dyer, a fungal biologist at the University of Nottingham in England, suspected that P. chrysogenum would reproduce sexually if given the right encouragement. A complete sequencing of the fungi’s genome revealed that P. chyrosogenum still carried the genes needed for mating. “That told us that there was perhaps sexual compatibility there,” he says. So Dyer and researchers at several other European institutions tried to find the ideal conditions that would encourage P.chrysogenum to have sex.

First, Dyer and his colleagues paired strains with compatible mating genes (P. chyrosogenum has two different sexes) and grew them with different food and light conditions. The winning combination was an oatmeal-base supplemented with a vitamin called biotin. After five weeks in the dark, the fungi produced special structures called cleistothecia and ascospores, which only occur after sexualreproduction. Genetic analysis confirmed that genes had been sexually recombined. “We’ve now revealed its secret sexual side,” Dyer says.

Furthermore, the researchers discovered that the genes that regulate the fungi’s sexual ability also control the amount of penicillin it produces; the fungi that are having sex make more penicillin. The team published their findings online in January in Proceedings of the National Academy of Sciences. “I’ve believed for a long time that these guys were having sex but they were just doing it in secret,” says Joan W. Bennett, a professor of plant biology and pathology at Rutgers University, who was not involved in the work.

Researchers are hoping that this leads to more efficient penicillin production or maybe even the discovery of new antibiotics.

mapping human sex cells

Exciting studies on human reproductive cells are profiled in Nature:

Even though the reproductive age for humans is around 15–45 years old, the precursor cells that go on to produce human eggs or sperm are formed much earlier, when the fertilized egg grows into a tiny ball of cells in the mother’s womb. This ball of cells contains ‘pluripotent stem cells’ — blank slates that can be programmed into any type of cell in the body — and researchers are hoping to use these stem cells to treat various conditions, including infertility.

 

But little is known about the early developmental stages of human gametes — owing to the sensitivity of working with human tissue — and most work in this area has been conducted using mice. In a Nature Cell Biology paper today1, researchers from the University of California, Los Angeles, trace the development of early germ cells in human fetuses of between 6 to 20 weeks and analysed when genes were turned on or off.

 

The DNA within these early germ cells carries ‘epigenetic modifications’ — structural changes that do not affect the DNA sequence itself but do affect the way that genes are expressed. These changes may have accumulated during the parents’ lives, and need to be erased during the fetal stage. The study found two major events that wipe out, or reprogram, epigenetic modifications. Most of this reprogramming happened before 6 weeks, but the authors found a second event that completes the reprogramming after 6 weeks.

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