rs2287161 — CRY1 3' Downstream G>C

CRY1 — The Metabolic Gatekeeper of Your Circadian Clock

Cryptochrome 1 (CRY1) is one of the core circadian clock genes that governs the 24-hour rhythms of nearly every cell in your body. Unlike the better-known CLOCK¹¹ CLOCK
core circadian transcription factor and PER genes²² PER genes
Period genes that form repressive complexes with CRY, CRY1 serves a dual role: it is both a circadian repressor that shuts down CLOCK:BMAL1 transcription³³ shuts down CLOCK:BMAL1 transcription
by competing with coactivators for binding to BMAL1's C-terminal transactivation domain and a metabolic regulator that directly controls hepatic glucose production⁴⁴ hepatic glucose production
through FOXO1 degradation pathways.

The rs2287161 variant sits in a regulatory region 3' downstream of the CRY1 gene on chromosome 12, likely affecting transcription factor binding⁵⁵ transcription factor binding
predicted to alter binding sites for multiple transcription factors in adipocytes and liver cells. This variant doesn't change the protein itself but rather influences how much CRY1 is produced and when — with profound effects on both circadian timing and metabolism.

The Mechanism

CRY1 acts as the molecular brake pedal of the circadian clock. During the day, CLOCK:BMAL1 drives the expression of Period and Cryptochrome genes. As CRY1 protein accumulates, it binds directly to both CLOCK and BMAL1 subunits⁶⁶ binds directly to both CLOCK and BMAL1 subunits
forming the central linchpin of vertebrate circadian repressive complexes, shutting down its own transcription and closing the 24-hour feedback loop. Mutations that enhance this repressive function — such as the familial CRY1Δ11 variant⁷⁷ CRY1Δ11 variant
which causes delayed sleep phase disorder by strengthening CRY1's grip on CLOCK:BMAL1 — lengthen circadian period and delay sleep timing.

But CRY1's role extends far beyond sleep. In the liver, CRY1 is rhythmically expressed and acts as a metabolic switch⁸⁸ metabolic switch
activated by insulin-induced SREBP1c to suppress gluconeogenesis. After a meal, rising insulin triggers SREBP1c (a master regulator of lipid synthesis), which in turn upregulates CRY1. Elevated CRY1 then promotes the degradation of FOXO1 — a transcription factor that drives the expression of gluconeogenic genes like PEPCK and G6Pase. This cascade ensures that the liver stops making glucose when you've just eaten. When CRY1 is deficient or dysregulated, this metabolic brake fails, leading to hepatic insulin resistance⁹⁹ hepatic insulin resistance
with upregulation of pathways that impede insulin signaling and exacerbate FOXO1-driven gluconeogenesis.

The rs2287161 C allele appears to subtly alter this regulatory balance. While the exact molecular consequence is still being mapped, studies show that CC homozygotes display higher fasting blood sugar, higher BMI, and lower HDL¹⁰¹⁰ higher fasting blood sugar, higher BMI, and lower HDL
compared to GG carriers, and the effects are strikingly dependent on diet composition.

The Evidence

The most compelling evidence for rs2287161 comes from gene-diet interaction studies. In a landmark 2014 study¹¹¹¹ landmark 2014 study
Garaulet et al. CRY1 circadian gene variant interacts with carbohydrate intake for insulin resistance in two independent populations: Mediterranean and North American. Cell Metabolism, 2014 involving 1,548 participants from Mediterranean and North American cohorts, researchers found a striking interaction: an increase in the proportion of carbohydrate intake led to a significant increase in HOMA-IR (a measure of insulin resistance) and fasting insulin, and a decrease in QUICKI (insulin sensitivity), exclusively among CC homozygotes. GG and GC carriers showed no such metabolic penalty from higher carbohydrate intake. The effect size was substantial — for every 10% increase in carbohydrate as a percentage of total energy intake, CC carriers experienced a 0.2-unit increase in HOMA-IR (p = 0.003 in the meta-analysis).

A 2021 Iranian study¹²¹² 2021 Iranian study
Ranjbar et al. Variants of the CRY1 gene may influence the effect of fat intake on resting metabolic rate in women with overweight or obesity. BMC Endocrine Disorders, 2021 (n = 377 women with overweight/obesity) found that high fat intake combined with the CC or GC genotypes was associated with significantly lower resting metabolic rate (RMR) per fat-free mass (p = 0.05) and RMR per BMI (p = 0.02), along with higher fasting blood sugar (p = 0.04). The authors concluded that CRY1 genotype modulates the metabolic response to dietary fat, with C allele carriers showing blunted metabolic rate when fat intake is high.

Beyond glucose and metabolism, the C allele also affects mood and circadian timing. A Chinese case-control study¹³¹³ Chinese case-control study
Hua et al. CRY1 and TEF gene polymorphisms are associated with major depressive disorder in the Chinese population. Journal of Affective Disorders, 2014 (n = 105 MDD cases, 485 controls) found that MDD patients had a significantly higher frequency of the C allele and CC genotype compared to controls (OR not reported, but p < 0.05). Mechanistic analysis suggested that rs2287161 acts through circadian phase advance¹⁴¹⁴ circadian phase advance
shifting the clock earlier, which paradoxically increases MDD risk in certain populations, potentially through misalignment between internal rhythms and social schedules.

Interestingly, the C allele is not uniformly detrimental. A 2021 cross-sectional study¹⁵¹⁵ 2021 cross-sectional study
Sadeghian et al. Variants in circadian rhythm gene CRY1 interact with healthy dietary pattern for serum leptin levels. Clinical Nutrition Research, 2021 found a significant gene-diet interaction: among participants following a healthy dietary pattern (high in vegetables, fruits, whole grains, low in processed foods), CC carriers had lower BMI and lower serum leptin compared to GG carriers (p = 0.034 for BMI). This suggests that the C allele's metabolic effects are highly context-dependent — protective in the context of a high-quality diet, harmful in the context of high carbohydrate or high fat intake.

Population genetics reveal that the C allele is common globally (minor allele frequency ~40%), with slight variation across ancestries. This suggests the variant is under balancing selection — likely because its effects depend so strongly on environmental context (diet, light exposure, meal timing).

Practical Actions

The key takeaway: if you carry one or two copies of the C allele, your metabolism is more sensitive to diet composition and timing. High carbohydrate intake and high fat intake both appear to exacerbate insulin resistance and metabolic dysfunction in C carriers, while a balanced, nutrient-dense dietary pattern mitigates these risks.

For sleep and mood, the C allele may subtly shift circadian phase, potentially contributing to mood dysregulation or seasonality. This makes consistent sleep-wake schedules, morning light exposure, and avoidance of late-night eating especially important for C carriers.

Interactions

CRY1 rs2287161 sits at the intersection of circadian rhythm genetics and metabolic regulation, interacting with multiple dietary and lifestyle factors.

Gene-gene interactions: CRY1 works in concert with other core clock genes including CLOCK rs1801260¹⁶¹⁶ CLOCK rs1801260
3111T>C variant affecting evening preference and sleep duration, PER2 rs2304672¹⁷¹⁷ PER2 rs2304672
regulatory variant influencing circadian timing, and PER3 rs228697¹⁸¹⁸ PER3 rs228697
Pro864Ala affecting chronotype. While no specific compound heterozygosity studies exist yet for rs2287161 + other clock gene variants, the biological pathway suggests that carrying risk alleles in multiple clock genes may compound circadian and metabolic dysfunction. For instance, a CC carrier at rs2287161 who also carries the CLOCK 3111C risk allele (associated with delayed sleep and shorter sleep duration) may experience amplified insulin resistance when eating late at night — a scenario where both circadian disruption (CLOCK) and metabolic dysregulation (CRY1) converge.

Gene-diet interactions (established): The rs2287161 genotype fundamentally changes how the body responds to macronutrient composition. CC homozygotes show insulin resistance specifically when carbohydrate intake is high (>50% of energy), and show lower resting metabolic rate when fat intake is high. Conversely, CC carriers following a balanced, whole-foods diet (measured by Alternative Healthy Eating Index or similar) show better metabolic outcomes than GG carriers — lower BMI, lower leptin, reduced cardiovascular risk factors.

Gene-meal timing interactions (probable but unstudied): Given CRY1's role in hepatic glucose production and its known interaction with MTNR1B rs10830963¹⁹¹⁹ MTNR1B rs10830963
melatonin receptor variant that impairs insulin secretion when meals are eaten late, it is plausible that rs2287161 CC carriers are particularly vulnerable to late-night eating. This interaction has not been formally tested but is mechanistically supported by CRY1's role in suppressing gluconeogenesis upon insulin signaling.

Gene-light exposure interactions (mechanistic): As a core clock gene, CRY1 is entrained by light. The rs2287161 variant may alter sensitivity to light-based circadian entrainment, though this has not been directly tested. If the C allele causes subtle phase advance (as suggested by the depression studies), morning light exposure may be especially important for C carriers to maintain proper alignment with social schedules.