Perhaps the most puzzling part:
We see a paradox: the rsRNA length shift is progressiveβ³yet the global RNA profile shows an "Aging Cliff"π.
Cliff or Progression? Maybe the gradual shift is the forerunnerβaccumulating silently until it triggers the cliff.
bsky.app/profile/qich...
A molecular "aging clock" has been identified in human sperm RNA, showing progressive changes with age that may influence offspring health and metabolism. doi.org/hbkmvf
Fascinating research! Qi Chen and colleagues have identified a potential "aging cliff" in sperm RNA (rsRNA) that is associated with the increased health risks for the next generation that accompany advancing paternal age. Read on uofuhealth.utah.edu/newsroom/new...
What underlies the impact of sperm aging on fertility and offspring health?
small ncRNA profiling by Kenneth Aston, Tong Zhou, @qichen-lab.bsky.social and colleagues reveals a drastic shift in RNA complements able to affect recipient cell metabolism
link.springer.com/article/10.1...
Perhaps the most puzzling part:
We see a paradox: the rsRNA length shift is progressiveβ³yet the global RNA profile shows an "Aging Cliff"π.
Cliff or Progression? Maybe the gradual shift is the forerunnerβaccumulating silently until it triggers the cliff.
bsky.app/profile/qich...
5/5 Connecting mouse and human sperm data to uncover this conserved rsRNA length shift has been a privilege. Made possible by unique resources at @uuhsresearch.bsky.social
Huge thanks to the trainees & collaborators who made this happen! @jianchengyu.bsky.social
@cai000chen.bsky.social
4/5 Crucially, beyond mouse data, we validated the sperm-head-specific rsRNA length shift signal in two independent human cohorts (longitudinal & cross-sectional).
This suggests an evolutionarily conserved feature, which may stem from shared (enzymatic) mechanisms during aging.
3/5 Perhaps the most surprising discovery: we see an age-dependent "Length Shift" in rsRNAs, exclusively found in sperm heads.
Specifically, longer fragments accumulate while shorter ones decrease with ageβa sign of altered RNA cleavage/processing efficiency (e.g., enzymatic).
2/5 The first revelation: In mice, PANDORA-seq uncovers a sharp "Aging Cliff"πin sperm RNA profiles at mid-lifeβa non-linear shift distinct from chronological age.
Crucially, this cliff signal (genomic & mitochondrial tsRNAs/rsRNAs) is invisible to traditional small RNA-seq.
1/5 It took us some time to connect the dots...now in @embojournal.org we use PANDORA-seq to start decoding the 'sperm RNA code of aging'
We find a conserved rsRNA length shift that reflects aging in both mouse & human sperm, and an 'aging cliff' at mid-lifeπ§΅
link.springer.com/article/10.1...
A road trip to Monument Valley and the wonders of the west, as an anniversary of labβs 10th year operationβ¦look forward to the journey aheadβ¦
Glad to see this thoughtful piece in @quantamagazine.bsky.social on paternal epigenetic inheritance and the emerging 'Sperm RNA Code', featuring many active colleagues in the field.
Itβs a reminder that our actions may echo in the next generation(s) & there are immense unknowns to explore...
1/ Excited to share our new study with @brumbaugh-lab.bsky.social, out in @natbiotech.nature.com! P-bodies selectively sequester RNAs encoding cell fate regulators, often from the preceding developmental stage. Releasing these RNAs can drive changes in cell identity. 𧡠www.nature.com/articles/s41...
After developing PANDORA-seq to reveal hidden small RNAs (e.g., tsRNA, rsRNA) and SPORTS to annotate them, we now expand our toolchain with Tong Zhou lab: introducing FUSION, a tool that robustly interprets small RNA changes even in small or 1-on-1 datasets.
academic.oup.com/bioinformati...
Proud to work with a brave team @cai000chen.bsky.socialβ¬ @jianchengyu.bsky.socialβ¬ Xudong Zhang & Tong Zhouβthinking fearlessly to bring this piece together.
In a time of uncertainty, may this idea be a seed for springβ¦ Weβll see what evidence we and the community can bring, to confirm or refuteβ¦
Beyond inheritance, the model may also apply to cancer & neurodegeneration, where abnormal RNA structures could shape pathological cell states.
Perhaps misfolded RNAs β not just amyloid proteins β are the central structural entity driving disease.
Why the memory fades eventually - as often seen in epigenetic inheritance:
Two potential exits:
Active reset: when conditions normalize, condensates dissolve, RBPs shift, RNA refolds.
Passive fade: cells with stress-memory may grow slower, and are outcompeted over generations.
Memory propagation in cells β and across generations:
Newly folded RNAs bind stress-linked RBPs to assemble new condensates, passed on during cell division.
Even daughter cells never facing the original stress can inherit the RNA structural memory β and its stress-adapted traits.
The heart of the hypothesis: copying RNA shape.
Some RNAs can act as both template & catalyst, guiding new RNAs with the same sequence to fold the same way.
RNA alone is unstable, but RBPs stabilize the template, & condensates boost RNAβRNA interactionsβas a microreaction chamber
The model starts with RNA folding energy & a multistable landscape.
Under stress, RNA can adopt a new shapeβand if RNA-binding proteins βlockβ it in, that shape becomes a molecular memory of the stress.
Think Waddingtonβs epigenetic landscapeβbut for RNA folding energy valleys.
Perhaps our boldest hypothesisβ¦ we propose a model for RNA Structural Memory propagation in @natcellbio.nature.com where RNA conformation is reshaped by stress, locked by RBPs, copied prion-like in condensates & passed across generationsβall without altering DNA
rdcu.be/eBwPJ
Our π· May π· issue is online with a broad range of article topics and formats!
In their Opinion article (on the cover, too!), @qichen-lab.bsky.social and colleagues describe the interactions between small ncRNAs and Toll-like receptors.
Find the issue here: www.cell.com/trends/bioch...
Very glad to see our Sequential Activation Hypothesis highlighted on the cover @cp-trendsbiochem.bsky.social , linking small RNA-TLR interactions to autoimmune disease mechanisms.
#NewNProt for #genomewide characterization of a diverse set of #smallnoncodingRNAs in cells and tissues
We put together a step-by-step protocols for PANDORA-seq, now available in Nature Protocols @natprot.bsky.social , including the sample preparation for sperm, sperm heads; and the analyzing software SPORTS optimized for various types of small RNAs including tsRNAs, rsRNAs, and miRNAs. rdcu.be/egk1Z
Proud of @jianchengyu.bsky.social and the team for thinking fearlessly to put the ideas together!
This idea is driven by advanced sncRNA sequencing (e.g. PANDORA-seq), uncovering an expanding universe of tsRNA/rsRNA/ysRNA & more www.nature.com/articles/s41...
These sncRNAs go beyond RNAi, adopting aptamer-like roles by binding TLR7/8 to shape immune responses
www.jbc.org/article/S002...
TLR7/8 arenβt just triggered by viral RNAs, they can be potentially activated by a range of RNA resources: cell stress/death, RNA therapies, microbiome, and even dietary RNAs.
Uncovering these diverse triggers may pave new paths for preventing/treating autoimmune diseases.
How can abnormal small RNA biogenesis spark autoimmune disease? Our opinion @cp-trendsbiochem.bsky.social discuss a novel two-stage activation hypothesis that may explain why autoimmunity hits women harder, via small RNA-TLR7/8 interactions & augmented by autoantibodies.
www.cell.com/trends/bioch...
go.bsky.app/QkSL6S5
