Fishing for answers to autism puzzle

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Microscopy images of zebrafish brain development

Microscopy images of zebrafish brain development

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Sive Lab

CAMBRIDGE, Mass. —Fish cannot display symptoms of autism, schizophrenia, or other human brain disorders. However, a team of Whitehead Institute and MIT scientists has shown that zebrafish can be a useful tool for studying the genes that contribute to such disorders.

Led by Whitehead Member Hazel Sive, the researchers set out to explore a group of about two dozen genes known to be either missing or duplicated in about 1 percent of autistic patients. Most of the genes’ functions were unknown, but a new study by Sive and Whitehead postdocs Alicia Blaker-Lee, Sunny Gupta and, Jasmine McCammon, revealed that nearly all of them produced brain abnormalities when deleted in zebrafish embryos.

The findings, published online recently in the journal Disease Models & Mechanisms, should help researchers pinpoint genes for further study in mammals, says Sive, who is also professor of biology and associate dean of MIT’s School of Science. Autism is thought to arise from a variety of genetic defects; this research is part of a broad effort to identify culprit genes and develop treatments that target them.

“That’s really the goal — to go from an animal that shares molecular pathways, but doesn’t get autistic behaviors, into humans who have the same pathways and do show these behaviors,” Sive says.

Sive recalls that some of her colleagues chuckled when she first proposed studying human brain disorders in fish, but it is actually a logical starting point, she says. Brain disorders are difficult to study because most of the symptoms are behavioral, and the biological mechanisms behind those behaviors are not well understood, she says.

“That allows you to deduce that what you’re learning in fish corresponds to what that gene is doing in humans.”

“We thought that since we really know so little, that a good place to start would be with the genes that confer risk in humans to various mental health disorders, and to study these various genes in a system where they can readily be studied,” she says.

Those genes tend to be the same across species — conserved throughout evolution, from fish to mice to humans — though they may control somewhat different outcomes in each species.

In the latest study, Sive and her colleagues focused on a genetic region known as 16p11.2, first identified by Mark Daly, a former Whitehead Fellow who discovered a type of genetic defect known as a copy number variant. A typical genome includes two copies of every gene, one from each parent; copy number variants occur when one of those copies is deleted or duplicated, and this can be associated with pathology.

The central “core” 16p11.2 region includes 25 genes. Both deletions and duplications in this region have been associated with autism, but it was unclear which of the genes might actually produce symptoms of the disease. “At the time, there was an inkling about some of them, but very few,” Sive says.

Sive and her postdocs began by identifying zebrafish genes analogous to the human genes found in this region. (In zebrafish, these genes are not clustered in a single genetic chunk, but are scattered across many chromosomes.) The researchers studied one gene at a time, silencing each with short strands of nucleic acids that target a particular gene and prevent its protein from being produced.

For 21 of the genes, silencing led to abnormal development. Most produced brain deficits, including improper development of the brain or eyes, thinning of the brain, or inflation of the brain ventricles, cavities that contain cerebrospinal fluid. The researchers also found abnormalities in the wiring of axons, the long neural projections that carry messages to other neurons, and in simple behaviors of the fish. The results show that the 16p11.2 genes are very important during brain development, helping to explain the connection between this region and brain disorders.

Furthermore, the researchers were able to restore normal development by treating the fish with the human equivalents of the genes that had been repressed. “That allows you to deduce that what you’re learning in fish corresponds to what that gene is doing in humans. The human gene and the fish gene are very similar,” Sive says.

To figure out which of these genes might have a strong effect in autism or other disorders, the researchers set out to identify genes that produce abnormal development when their activity is reduced by 50 percent, which would happen in someone who is missing one copy of the gene. (This correlation is not seen for most genes, because there are many other checks and balances that regulate how much of a particular protein is made.)

The researchers identified two such genes in the 16p11.2 region. One, called kif22, codes for a protein involved in the separation of chromosomes during cell division, and one, aldolase a, is involved in glycolysis — the process of breaking down sugar to generate energy for the cell.

In work that has just begun, Sive’s lab is working with Stanford University researchers to explore in mice predictions made from the zebrafish study. They are also conducting molecular studies in zebrafish of the pathways affected by these genes, to get a better idea of how defects in these might bring about neurological disorders.

This research was funded by the Simons Foundation Autism Research Initiative.

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Hazel Sive’s primary affiliation is with Whitehead Institute for Biomedical Research, where her laboratory is located and all her research is conducted. Sive is also a professor of biology at Massachusetts Institute of Technology.

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Citation:

Blaker-Lee, A., Gupta, S., Mccammon, J. M., Rienzo, G. D., & Sive, H. (2012). Zebrafish homologs of genes within 16p11.2, a genomic region associated with brain disorders, are active during brain development, and include two deletion dosage sensor genes. Disease Models & Mechanisms, 5(6), 834-851. doi:10.1242/dmm.009944

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