Nearly five years ago, researchers suggested that the vast majority of preclinical cancer research wouldn’t hold up to follow-up experiments, delaying much needed treatments for patients. In a series of articles publishing tomorrow morning, eLife has released the results of the first five attempts to replicate experiments in cancer biology — and the results are decidedly mixed.

As our co-founders Adam Marcus and Ivan Oransky write in STAT, the overall take-home message was that two studies generated findings similar to the original, one did not replicate the original, and two others were inconclusive.

They quote Brian Nosek, a psychologist at the University of Virginia, in Charlottesville, who runs the Center for Open Science, who has been leading the replication effort in his own field:

Reproducibility is hard, and once you fail to reproduce something it isn’t always obvious why.

The new articles, added Nosek,

are additional evidence that we don’t quite understand this as well as we thought we did.

(Full disclosure: Retraction Watch is partnering with the Center on a database of retractions.)

This is just the first wave of results: The authors plan on performing and publishing more than 20 replication efforts. And they had hoped for more, Marcus and Oransky write:

The effort isn’t cheap: Each replication took an average of nearly seven months to complete, at an average cost of about $27,000, according to data from the investigators.  (Budget concerns had earlier forced the group to cut from 50 to 37 the number of trials they could re-run.)

The effort would be easier if researchers cooperated, they add:

Although many researchers the group contacted were gracious and eager to help – providing additional information about their methods – others were less forthcoming. One group took 111 days to respond; another ignored the request.

In an accompanying editorial publishing tomorrow, Nosek and Timothy Errington, the “metascience manager” at the Center for Open Science, caution that being able to replicate a result doesn’t automatically mean the result is correct — and vice versa:

Scientific claims gain credibility by accumulating evidence from multiple experiments, and a single study cannot provide conclusive evidence for or against a claim. Equally, a single replication cannot make a definitive statement about the original finding. However, the new evidence provided by a replication can increase or decrease confidence in the reproducibility of the original finding.

Indeed, as an accompanying editorial notes, one of the studies whose replication efforts produced somewhat inconclusive results has led to a clinical trial for an antibody therapy. Whether or not it is effective in patients remains to be seen.

For Adam and Ivan’s whole column, click here.

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Teresa Davoli, Hajime Uno, Eric C. Wooten, Stephen J. Elledge

Structured Abstract

CONCLUSION

We found that two hallmarks of cancer, cell proliferation and immune evasion, are predicted by distinct types of aneuploidy that likely act through distinct mechanisms. Proliferation markers mainly correlated with focal SCNAs, implying a mechanism related to the action of specific genes targeted by these SCNAs. Immune evasion markers mainly correlated with arm- and chromosome-level SCNAs, consistent with a mechanism related to general gene dosage imbalance rather than the action of specific genes. A retrospective analysis of melanoma patients treated with immune checkpoint blockade anti–CTLA-4 (cytotoxic T lymphocyte–associated protein 4) therapy revealed that high SCNA levels were associated with a poorer response, suggesting that tumor aneuploidy might be a useful biomarker for predicting which patients are most likely to benefit from this therapy.

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Molecular-level analysis of the serum antibody repertoire in young adults before and after seasonal influenza vaccination

Molecular understanding of serological immunity to influenza has been confounded by the complexity of the polyclonal antibody response in humans. Here we used high-resolution proteomics analysis of immunoglobulin (referred to as Ig-seq) coupled with high-throughput sequencing of transcripts encoding B cell receptors (BCR-seq) to quantitatively determine the antibody repertoire at the individual clonotype level in the sera of young adults before and after vaccination with trivalent seasonal influenza vaccine. The serum repertoire comprised between 40 and 147 clonotypes that were specific to each of the three monovalent components of the trivalent influenza vaccine, with boosted pre-existing clonotypes accounting for ~60% of the response. An unexpectedly high fraction of serum antibodies recognized both the H1 and H3 monovalent vaccines. Recombinant versions of these H1 + H3 cross-reactive antibodies showed broad binding to hemagglutinins (HAs) from previously circulating virus strains; several of these antibodies, which were prevalent in the serum of multiple donors, recognized the same conserved epitope in the HA head domain. Although the HA-head-specific H1 + H3 antibodies did not show neutralization activity in vitro, they protected mice against infection with the H1N1 and H3N2 virus strains when administered before or after challenge. Collectively, our data reveal unanticipated insights regarding the serological response to influenza vaccination and raise questions about the added benefits of using a quadrivalent vaccine instead of a trivalent vaccine.

http://www.pnas.org/content/early/2016/08/10/1607794113.full.pdf

Margaret L. Hoanga,b,1, Isaac Kindea,b,2, Cristian Tomasettic,d, K. Wyatt McMahona,b, Thomas A. Rosenquiste , Arthur P. Grollmane,f, Kenneth W. Kinzlera,3, Bert Vogelsteina,b,g,3, and Nickolas Papadopoulos

We present the bottleneck sequencing system (BotSeqS), a nextgeneration sequencing method that simultaneously quantifies rare somatic point mutations across the mitochondrial and nuclear genomes. BotSeqS combines molecular barcoding with a simple dilution step immediately before library amplification. We use BotSeqS to show age- and tissue-dependent accumulations of rare mutations and demonstrate that somatic mutational burden in normal human tissues can vary by several orders of magnitude, depending on biologic and environmental factors. We further show major differences between the mutational patterns of the mitochondrial and nuclear genomes in normal tissues. Lastly, the mutation spectra of normal tissues were different from each other, but similar to those of the cancers that arose in them. This technology can provide insights into the number and nature of genetic alterations in normal tissues and can be used to address a variety of fundamental questions about the genomes of diseased tissues.

Nat Methods. 2016 Aug;13(8):657-60. doi: 10.1038/nmeth.3895. Epub 2016 Jun 6.
Dense transcript profiling in single cells by image correlation decoding.
Coskun AF1,2, Cai L1,2.
Author information
Abstract
Sequential barcoded fluorescent in situ hybridization (seqFISH) allows large numbers of molecular species to be accurately detected in single cells, but multiplexing is limited by the density of barcoded objects. We present correlation FISH (corrFISH), a method to resolve dense temporal barcodes in sequential hybridization experiments. Using corrFISH, we quantified highly expressed ribosomal protein genes in single cultured cells and mouse thymus sections, revealing cell-type-specific gene expression.

PMID: 27271198 PMCID: PMC4965285 [Available on 2017-02-01] DOI: 10.1038/nmeth.3895

For those following the C9ORF72 story, this is a very interesting twist!

Loss-of-function mutations in the C9ORF72 mouse ortholog cause fatal autoimmune disease

Aaron Burberry1,2, Naoki Suzuki1,2, Jin-Yuan Wang1,2, Rob Moccia1,2, Daniel A. Mordes1,2,3, Morag H. Stewart1,4, Satomi Suzuki-Uematsu1,2, Sulagna Ghosh1,2, Ajay Singh1,2, Florian T. Merkle1,2, Kathryn Koszka1,2, Quan-Zhen Li5, Leonard Zon1,6, Derrick J. Rossi1,4,6, Jennifer J. Trowbridge7, Luigi D. Notarangelo6,8 and Kevin Eggan1,2,*

Abstract

C9ORF72 mutations are found in a significant fraction of patients suffering from amyotrophic lateral sclerosis and frontotemporal dementia, yet the function of the C9ORF72 gene product remains poorly understood. We show that mice harboring loss-of-function mutations in the ortholog of C9ORF72 develop splenomegaly, neutrophilia, thrombocytopenia, increased expression of inflammatory cytokines, and severe autoimmunity, ultimately leading to a high mortality rate. Transplantation of mutant mouse bone marrow into wild-type recipients was sufficient to recapitulate the phenotypes observed in the mutant animals, including autoimmunity and premature mortality. Reciprocally, transplantation of wild-type mouse bone marrow into mutant mice improved their phenotype. We conclude that C9ORF72 serves an important function within the hematopoietic system to restrict inflammation and the development of autoimmunity.