Fact-checked by Grok 2 weeks ago

Phenocopy

A phenocopy is a phenotypic trait or disease that resembles the expression of a particular genotype but arises in an individual who does not carry that genotype, typically due to environmental influences rather than genetic mutation.^[1] This phenomenon highlights the complex interplay between genes and environment in shaping observable characteristics.^[2] The term was first coined in 1935 by geneticist Richard Goldschmidt during his studies on fruit flies (Drosophila melanogaster), where he observed environmentally induced abnormalities that mimicked hereditary mutants.^[3] Phenocopies have been instrumental in developmental and evolutionary biology, demonstrating how external stressors—such as temperature changes, chemicals, or nutritional deficits—can disrupt normal development to produce mutant-like forms.^[4] Classic examples include the bithorax phenocopy in Drosophila, induced by heat shock during larval stages, which replicates the wing morphology of the genetic bithorax mutant.^[4] In mammals, Himalayan rabbits (genotype ch/ch) exhibit a phenocopy of the full-color genotype when raised in cold conditions, developing a darker coat resembling genetically black rabbits, which underscores temperature-sensitive gene expression. The standard Himalayan phenotype features dark pigmentation on extremities (cooler body parts) that reduces in warmer conditions.^[2] In medicine, phenocopies complicate genetic diagnosis and risk assessment, as they can mimic hereditary diseases without underlying mutations, affecting conditions like breast cancer in BRCA1 families or retinitis pigmentosa.^[5]^[6] For instance, environmental or sporadic factors may produce breast cancer phenotypes in non-carriers, leading to overestimation of familial risk if phenocopies are not identified.^[5] Similarly, in pharmacogenomics, certain drugs can induce a phenocopy of poor metabolizer genotypes, such as CYP2D6 inhibition mimicking genetic variants and altering drug responses.^[7] Recognizing phenocopies is crucial for accurate differential diagnosis, personalized medicine, and understanding gene-environment interactions in disease etiology.^[8]

Definition and History

Definition

A phenocopy is an environmentally induced phenotypic variation that mimics the observable traits (phenotype) produced by a specific genetic mutation, but occurs in individuals without that genetic alteration; it is non-heritable and typically reversible upon removal of the environmental trigger.^[9] The term was coined by geneticist Richard Goldschmidt in 1935 to describe such environmentally produced forms resembling genetic mutants, as observed in experiments with Drosophila.^[10] Unlike genetic phenotypes, which result from heritable changes in the DNA sequence, phenocopies emerge from gene-environment interactions that modify gene expression without altering the genotype itself.^[11] This distinction highlights how external factors can temporarily override or simulate genetic effects, emphasizing the role of phenotypic plasticity in development.^[12] This phenomenon acts as a "fake-out" in genetics, where the environment impersonates a mutation without affecting heredity. For example, heat shock in Drosophila can induce phenocopies of wing mutations.^[12]

Historical Development

The term "phenocopy" was introduced by German geneticist Richard Goldschmidt in 1935 to describe environmentally induced phenotypic variations in Drosophila melanogaster that closely resembled those caused by genetic mutations.^[12] This concept built upon Goldschmidt's earlier research in 1929, which explored developmental plasticity in insects through experimental manipulations of environmental factors during ontogeny.^[13] Goldschmidt's foundational observations stemmed from experiments where temperature fluctuations and chemical exposures during specific developmental stages produced mutant-like wing malformations in fruit flies, highlighting the role of external influences in mimicking hereditary traits without altering the genome.^[14] In the 1940s and 1950s, British developmental biologist C.H. Waddington significantly advanced the phenocopy framework through his experiments on genetic assimilation. Waddington demonstrated that repeated induction of phenocopies—such as crossveinless wing phenotypes triggered by heat shock—in Drosophila populations over generations could result in the trait becoming genetically fixed and expressed even without the environmental stimulus, suggesting a canalization of environmentally induced variation into heritable form.^[15] His seminal 1953 study provided empirical evidence for this process, bridging phenocopies with evolutionary developmental biology and challenging strict genocentric views of inheritance. Post-1950s developments saw phenocopies increasingly linked to epigenetics and non-genetic inheritance mechanisms during the 1970s and 1980s, as researchers explored how environmental perturbations could propagate phenotypic effects across generations via cytoplasmic or regulatory factors rather than DNA sequence changes.^[13] The concept revived in the 2000s with molecular tools like RNA interference (RNAi), which enabled precise induction of phenocopies to probe gene functions; for instance, RNAi-mediated knockdowns in insects phenocopied homeotic mutations, facilitating comparative studies of orthologous genes across species.^[16] Later integrations with CRISPR-Cas9 editing further validated phenocopies for dissecting gene roles in development and disease.^[17] As of 2025, computational models have explored the evolution of phenocopying mechanisms in developmental trajectories, while proteogenomic studies have applied phenocopy concepts to identify cancer vulnerabilities without genetic mutations.^[18]^[17] Key milestones in the literature include Goldschmidt's 1935 paper "Gen und Außeneigenschaft," which formalized the term; Waddington's 1953 "Genetic Assimilation of an Acquired Character"; and 21st-century reviews that reposition phenocopies within systems biology, emphasizing their utility in high-throughput functional genomics and phenotypic screening.^[19]

Mechanisms

Environmental Influences

Environmental influences play a pivotal role in inducing phenocopies, where external factors disrupt normal development to produce phenotypes resembling those caused by genetic mutations. Temperature extremes, particularly heat shocks, are among the primary agents; for instance, exposing Drosophila pupae to 40°C for approximately 1 hour during specific imaginal disc development stages can induce a range of morphological abnormalities, such as crossveinless wings, bithorax transformations, and notched wings, mimicking recessive mutants.^[20] Chemical exposures, including toxins like sodium metaborate, similarly trigger phenocopies; at concentrations around 0.003-0.009 g/liter in culture media, this boron-containing salt causes eye reductions, rough eye surfaces, and antennal modifications in Drosophila larvae, phenocopying eyeless or rough mutants.^[21] Nutritional deficits, such as deficiencies in pantothenic acid during Drosophila oogenesis, can modify maternal effects to produce phenotypes resembling maroon-like mutants, with altered eye pigmentation and viability.^[22] The severity of phenocopies induced by these environmental agents depends on dose-response relationships, encompassing the intensity, timing, and duration of exposure. Higher intensities, such as elevated heat shock temperatures or increased chemical concentrations, amplify phenotypic defects; for sodium metaborate, doses near lethality (e.g., 0.009 g/liter) result in complete eyelessness, while lower doses produce milder roughening.^[21] Critical developmental windows heighten susceptibility, as interventions during sensitive periods—like 48-78 hours post-larval hatching for chemical effects or pupal stages 0-24 hours after pupariation for heat shocks—maximize phenocopy induction by coinciding with key morphogenetic events.^[21] Prolonged durations exacerbate outcomes; extended heat exposure beyond 60 minutes at 40°C increases the frequency and complexity of multiple phenocopies, such as combined wing and haltere defects.^[20] Other triggers include mechanical stress and radiation or pollutants. Mechanical injury to developing limb buds in amphibians, such as tadpole forelimb perturbations during metamorphosis, can cause malformations like ectrodactyly or polydactyly, phenocopying genetic limb mutants by disrupting apical ectodermal ridge signaling.^[23] Radiation exposure, exemplified by ultraviolet light at doses of 500-2000 erg/mm² on Drosophila eggs, induces wing vein disruptions and eye abnormalities, resembling crossveinless or singed mutants without altering the germline genotype.^[24] Non-genotoxic carcinogens, such as peroxisome proliferators, can promote cancer-like phenotypes including hepatic hyperplasia and tumor promotion in exposed tissues without inducing oncogenic DNA mutations, by activating PPARα and overriding normal proliferative controls.^[25] Hormones like diethylstilbestrol (DES) similarly induce tumor formation through hormonal disruption and cell proliferation, independent of DNA damage.^[26] The baseline genetic robustness, or canalization, of an organism modulates susceptibility to these environmental triggers, determining how readily normal development is overridden. Highly canalized genotypes maintain phenotypic stability across environmental variations, reducing phenocopy frequency; for example, wild-type Drosophila strains exhibit lower rates of heat-induced abnormalities compared to less robust mutants, as canalization buffers perturbations through redundant developmental pathways.^[27] However, when environmental stressors exceed canalization thresholds, they disrupt these buffers, leading to pronounced phenocopies even in genetically robust backgrounds.^[27]

Molecular and Genetic Processes

Environmental signals can disrupt normal gene expression patterns by interfering with transcription factors, resulting in altered protein levels that mimic genetic mutant phenotypes. For instance, heat shock activates stress-response pathways that lead to the synthesis of heat shock proteins (HSPs), which in turn exert feedback inhibition on general RNA synthesis, thereby downregulating transcription of developmental genes.^[20] This modulation often targets key regulatory genes, such as Hox genes, where environmental stressors like ether or heat induce proteotoxic stress, compromising chaperone functions like Hsp90 and leading to decreased expression levels that produce homeotic-like transformations. Epigenetic modifications provide a mechanism for environmentally induced phenocopies by altering chromatin structure without changing the DNA sequence, creating temporary "memory" effects that persist through cell divisions. Environmental cues, such as temperature fluctuations, can trigger DNA methylation via enzymes like DNMT3, repressing gene promoters by recruiting methyl-CpG-binding proteins and compacting chromatin to silence transcription.^[28] Similarly, histone modifications, including reduced H3K4 trimethylation due to disrupted Trithorax function under stress, maintain altered epigenetic states that favor ectopic gene activation or repression, mimicking heritable mutants in a reversible manner. These changes allow cells to respond adaptively to perturbations while preserving developmental potential. Signaling pathways, particularly stress-response cascades, reroute developmental processes to generate phenocopies by amplifying initial environmental inputs. Heat shock proteins not only inhibit transcription but also redirect cellular resources toward survival, altering downstream cascades like those involving Polycomb and Trithorax groups that regulate Hox loci.^[20] Positive feedback loops within these pathways can stabilize the perturbed state; for example, initial stress-induced epigenetic shifts enhance sensitivity to further signals, propagating the effect through developmental stages. Qualitative models, such as threshold models, describe how phenocopies arise when environmental perturbations shift underlying genetic liability beyond a critical tipping point, leading to discrete phenotypic switches. In this framework, developmental traits with continuous genetic underpinnings express discretely only when liability exceeds a threshold, which heat shock or other stressors lower by increasing variance in gene activity.^[29] This results in a subset of individuals exhibiting the phenocopy, akin to canalization breakdown, without requiring genetic change.^[28]

Examples

In Insects

One of the classic examples of phenocopies in insects is the bithorax transformation in Drosophila melanogaster, where environmental stress mimics the genetic bithorax mutation, resulting in the conversion of halteres into wing-like structures and producing four-winged flies. In seminal experiments by Conrad H. Waddington, exposure of pupae aged 21–23 hours to a heat shock of 40°C for 4 hours induced this phenocopy, with an initial incidence rate of approximately 2% in wild-type strains.^[30] This pupal-stage treatment disrupts normal development of the third thoracic segment, highlighting heat as a trigger for homeotic-like shifts.^[31] Ether vapor exposure has also been used to induce wing-related phenocopies in Drosophila, often producing transformations similar to genetic mutants affecting wing morphology, such as reductions or duplications in venation and shape. Richard Goldschmidt's early work demonstrated that brief ether treatment during embryonic stages leads to reproducible defects in wing development, mimicking dominant mutations like those in the bithorax complex by altering haltere formation.^[32] For instance, ether vapor applied to early embryos disrupts segment organization, yielding phenocopies with curled or irregular wing structures akin to the Curly mutant phenotype.^[33] Beyond Drosophila, phenocopies occur in other insects, such as butterflies, where temperature variations during pupal development induce color patterns that mimic genetic melanic mutants. In the buckeye butterfly Junonia coenia, lower rearing temperatures produce darker wing melanization, phenocopying melanic genetic variants and demonstrating thermal plasticity in pigmentation pathways.^[34] Similarly, in locusts like Locusta migratoria, crowding density triggers phase changes from solitary to gregarious forms, with the latter exhibiting bolder coloration, swarming behavior, and morphology that parallels certain genetic mutants in pigmentation and body form.^[35] These density-dependent shifts, while a form of polyphenism, function as phenocopies by environmentally replicating heritable traits without genetic alteration.^[36] The experimental reproducibility of insect phenocopies, particularly in Drosophila, benefits from the model's short generation time and genetic tractability, enabling precise control over induction rates and phenotypic scoring in laboratory settings. Standardized protocols for heat or chemical shocks yield consistent low-incidence rates (1–5%) across replicates, facilitating quantitative analysis of environmental impacts on development.^[37] This reliability has made Drosophila a cornerstone for studying phenocopy mechanisms since the mid-20th century.^[38]

In Vertebrates

Phenocopies in vertebrates often arise from environmental perturbations that disrupt conserved developmental pathways, mimicking hereditary mutations without altering the underlying genome. A prominent example occurs in amphibians, where excess vitamin A administration to salamander embryos induces limb defects resembling genetic polydactyly. This phenocopy results from the teratogenic effects of retinoic acid, a metabolite of vitamin A, which interferes with the proximal-distal axis of limb development by altering signaling gradients in the limb bud. Specifically, elevated retinoic acid levels cause posteriorization and duplication of digits, closely replicating the phenotype of mutations in genes like those regulating Hox expression, as demonstrated in classic experiments with Ambystoma mexicanum. In avian species, environmental stressors can produce beak malformations that phenocopy genetic anomalies. For instance, in chickens (Gallus gallus domesticus), exposure to abnormal temperatures or nutritional deficiencies during embryonic development leads to crossbeak deformities, where the upper and lower beak axes fail to align properly. This mimics the recessive genetic mutation talpid, involving disrupted midline signaling in the frontonasal prominence, but is triggered by transient factors like hyperthermia that affect neural crest cell migration and cartilage formation. Such induced phenocopies have been observed in controlled incubations at elevated temperatures around 40°C, highlighting the sensitivity of avian craniofacial development to thermal cues. Mammalian coat color patterns provide another well-studied vertebrate phenocopy, particularly in rabbits. The Himalayan phenotype in rabbits carrying the temperature-sensitive c^h allele is characterized by dark pigmentation on extremities and lighter fur on the trunk due to thermolabile tyrosinase enzyme activity, which functions below 35°C. When raised in colder environments (e.g., 15–20°C), these rabbits exhibit increased darkening, phenocopying full-color patterns in cooler regions. This underscores the role of environmental temperature in modulating pigment enzyme kinetics in genetically predisposed animals.

In Humans

Metabolic disorders provide another key example, where iodine deficiency during pregnancy or early infancy causes endemic goiter and cretinism, manifesting as hypothyroidism, intellectual impairment, and growth retardation that closely mimic congenital thyroid enzyme defects like dyshormonogenesis due to genetic mutations in genes such as DUOX2 or TG.^[39] Unlike genetic forms, these environmental cases respond to iodine supplementation, preventing permanent sequelae and illustrating how nutritional deficits can phenocopy inborn errors of thyroid hormone synthesis.^[40] Detection of phenocopies relies on genetic testing, including karyotyping, chromosomal microarray, or targeted sequencing, to differentiate phenocopies from true mutations by confirming the absence of genetic alterations while identifying reversible environmental contributors.

Applications and Implications

In Evolutionary Biology

In evolutionary biology, phenocopies play a pivotal role in genetic assimilation, a process where environmentally induced phenotypes become genetically fixed through natural selection. Conrad Hal Waddington demonstrated this in his classic experiments with Drosophila melanogaster, where exposure to high temperatures during development produced a bithorax phenocopy—a transformation of the third thoracic segment into a second—mimicking a known genetic mutation. After several generations of selective breeding for this induced trait, the phenocopy appeared in offspring even without the environmental stressor, indicating that selection had canalized the phenotype genetically.^[41] This assimilation highlights how phenocopies can bridge environmental plasticity and heritable variation, accelerating evolutionary change by stabilizing adaptive responses in populations.^[30] Phenocopies also enhance evolvability by acting as provisional expressions of cryptic genetic variation, serving as "trial runs" that reveal potential mutations without immediate fitness costs. Environmental perturbations can disrupt developmental buffering mechanisms, such as those involving chaperone proteins like Hsp90, which normally suppress phenotypic variation; inhibiting Hsp90 induces phenocopies that expose underlying genetic diversity, allowing selection to act on beneficial variants.^[42] This buffering against stress facilitates the breakdown of canalization, enabling populations to explore novel phenotypes rapidly in fluctuating environments and increasing the likelihood of adaptive evolution. The adaptive significance of phenocopies is evident in natural systems like seasonal polyphenism in insects, where environmental cues induce discrete, heritable-like phenotypic shifts that enhance survival and reproduction. For instance, in butterflies such as Bicyclus anynana, temperature and photoperiod trigger alternative wing patterns—darker, cryptic forms in dry seasons for thermoregulation and lighter, conspicuous ones in wet seasons for mate attraction—allowing the same genotype to produce contextually optimal phenotypes.^[43] These environmentally driven variations mimic genetic polymorphisms and promote rapid adaptation to seasonal stresses, as seen in their correlation with improved fitness metrics like survival rates under varying light and temperature conditions.^[44] Modern studies further reveal epigenetic phenocopies in wild populations, where non-genetic modifications influence fitness without altering DNA sequences. These findings underscore how epigenetic phenocopies provide a flexible layer of adaptation, buffering genetic change while facilitating long-term evolutionary responses.

In Medical and Genetic Research

In medical and genetic research, phenocopies serve as powerful tools for validating gene functions by replicating mutant phenotypes through transient interventions. In zebrafish models, RNA interference (RNAi) techniques, particularly morpholino oligonucleotides (MOs), are employed to knock down specific genes and produce phenocopies of known developmental mutants, thereby confirming the gene's role in observed phenotypes. For instance, splice-site MOs targeting the histone gene h2afza have successfully phenocopied transposon-induced mutations, demonstrating how such knockdowns can isolate gene contributions in large-scale forward genetic screens for developmental processes.^[45] Similarly, guidelines emphasize using multiple MOs or complementary CRISPR approaches to ensure specificity, with rescue experiments via mRNA injection further validating the phenocopy as a direct result of gene perturbation rather than off-target effects. This method has been instrumental in zebrafish screens, accelerating the identification of genes involved in organogenesis and congenital disorders. Phenocopy assays also play a critical role in drug discovery by identifying small molecules that mimic loss-of-function mutations, thereby facilitating target validation and therapeutic development. In zebrafish-based high-throughput screens, chemical compounds are tested for their ability to phenocopy genetic defects in models of cancer and neurodegeneration, linking bioactive hits to specific pathways and expediting candidate drug prioritization. For example, phenothiazine derivatives like perphenazine were identified in zebrafish T-ALL models as activators of protein phosphatase 2A (PP2A), leading to tumor suppression and apoptosis in vivo, which informed repurposing strategies for existing antimalarials.^[46] In neurodegeneration, compounds like optovin photoactivate wild-type TRPA1 channels in zebrafish sensory neurons to induce responses mimicking activated states, revealing novel targets for neuroactive drugs and highlighting polypharmacology opportunities.^[47] These assays reduce the time from hit identification to mechanism elucidation, enhancing efficiency in oncology and neurological therapeutics. Distinguishing phenocopies from true genetic diseases is essential for accurate diagnosis, often relying on detailed environmental histories and epigenomic profiling to uncover non-genetic triggers. In conditions like steroid-resistant nephrotic syndrome (SRNS), environmental exposures such as toxins or infections can induce podocyte injury that mimics mutations in genes like NPHS1 or WT1, leading to proteinuria without heritable variants. Epigenomic analyses, including DNA methylation patterns and histone modifications, reveal how such exposures alter gene expression without sequence changes, enabling differentiation from monogenic forms. Integrating patient history with whole-exome sequencing has identified phenocopies in approximately 5% of presumed hereditary cases, reducing misdiagnosis rates and avoiding inappropriate genetic counseling or therapies.^[48] This approach, informed by human disease mimics like environmentally induced autism-like traits, underscores the need for multidisciplinary diagnostics. Looking ahead, phenocopies are poised for integration with CRISPR technologies to create "reverse phenocopies," where genetic edits induce states resembling environmental perturbations, offering insights into gene-environment interactions. For example, CRISPR/Cas9-mediated knockouts of activin receptors (Acvr2a/Acvr2b) in adult mouse muscle have phenocopied hypertrophy from myostatin inhibition, mimicking exercise-induced growth without physical stress.^[49] Such tools could model environmentally driven diseases genetically, aiding precision medicine. However, advancing to human trials raises ethical considerations, including equitable access, off-target risks, and informed consent for heritable edits, as emphasized in frameworks for germline modifications. These developments promise to refine therapeutic strategies while necessitating robust oversight to balance innovation with societal equity.

References

[1]
Definition of phenocopy - NCI Dictionary of Genetics Terms
A phenotypic trait or disease that resembles the trait expressed by a particular genotype but in an individual who is not a carrier of that genotype.
[2]
Phenocopy – A Strategy to Qualify Chemical Compounds during Hit ...
A phenocopy is defined as an environmentally induced phenotype of one individual which is identical to the genotype-determined phenotype of another individual.
[3]
The Genetic Material? - RNA, the Epicenter of Genetic Information
Goldschmidt also coined the term 'phenocopy' to describe morphological changes in Drosophila that could be induced by imposition of stress during ...
[4]
Development and genetic analysis of bithorax phenocopies ... - Nature
Aug 9, 1974 · PHENOCOPIES are developmental abnormalities which closely resemble known mutants, and can be induced experimentally1. Phenocopies of a given ...Missing: definition | Show results with:definition
[5]
Phenocopies in breast cancer 1 (BRCA1) families - NIH
For example, a family with two sisters affected with breast cancer might be offered testing, whereas a family with one affected woman would not. We infer, ...
[6]
Phenocopy of a heterozygous carrier of X-linked retinitis pigmentosa ...
Jan 8, 2021 · We describe both phenotype and pathogenesis in two male siblings with typical retinitis pigmentosa (RP) and the potentially X-linked RP ...
[7]
Genomic Medicine 2 Pharmacogenomics - The Lancet
Aug 10, 2019 · drug metabolism pathways, described as a phenocopy. Examples of phenocopies include CYP2D6 inhibition by some selective serotonin-reuptake ...
[8]
Phenocopy in a patient with triple negative breast cancer
In phenocopies, phenotypes identical to those with genetic origin occur because of environmental factors rather than familial mutations. We describe a case of ...
[9]
(PDF) Phenocopy – A Strategy to Qualify Chemical Compounds ...
A phenocopy is defined as an environmentally induced phenotype of one individual which is identical to the genotype-determined phenotype of another ...
[10]
The induction of a multiple wing hair phenocopy by heat shock in ...
Goldschmidt, 1935. R. Goldschmidt. Gen. and Ausseneigenschaft. Zeits. indukt. Abst. u. Vererb, 69 (1935), pp. 38-131. View in Scopus Google Scholar. Lewis, 1968.
[11]
Phenocopy - an overview | ScienceDirect Topics
A phenocopy is defined as an individual exhibiting a phenotype associated with a genetic variant, despite lacking that variant. This phenomenon can arise from ...
[12]
Environmentally Induced Development Defects in Drosophila
1. Goldschmidt coined the name “phenocopy” to describe environmentally induced developmental defects. This name was chosen in order to emphasize the resemblance ...<|control11|><|separator|>
[13]
Look Alike, Sound Alike: Phenocopies in Steroid-Resistant ... - MDPI
Nov 12, 2020 · A comprehensive genetic testing in SRNS should therefore comprise phenocopy genes in order to provide a conclusive diagnosis and correctly ...
[14]
[PDF] phenocopies, heredity and evolution¹
Goldschmidt (1938, 1945) extended Jollos' hypothesis by suggesting that the observed pattern of phenocopy production indicated the existence of two quite ...
[15]
NEW EXPERIMENTS ON CHEMICAL PHENOCOPIES* - PNAS
In his early work on heat-induced phenocopies Goldschmidt' had shown that the ... there are many facts which require the old definitionof phenocopies as induced,.
[16]
[PDF] Genetic Assimilation of an Acquired Character - Inters.org
It was decided to select a strain of Dros- phila melanogaster for its ability to form a phenocopy in response to some definite environmental stimulus. It was ...
[17]
Using RNAi to investigate orthologous homeotic gene function ...
Dec 24, 2001 · Using RNAi to investigate orthologous homeotic gene function during development of distantly related insects ... phenocopy null mutations. We show ...
[18]
Proteogenomic discovery of RB1-defective phenocopy in cancer ...
Mar 26, 2025 · Using RNA interference and a CRISPR-Cas9 screen in isogenic models, we find that RBness cancers also phenocopy synthetic lethal ...
[19]
Phenocopy – A Strategy to Qualify Chemical Compounds during Hit ...
A phenocopy is defined as an environmentally induced phenotype of one individual which is identical to the genotype-determined phenotype of another individual.
[20]
[PDF] [ 392 ] pi~oduction of phenocopies in drosophila usin~ salts, pai ...
(i) The lethal concentration of metaborate is lowest for the wild-type and highest for the heterozygo-us llies. The toxic effect is, therefore, at least partly ...
[21]
The effects of nutritional deficiencies on the maroon-like maternal ...
Apr 14, 2009 · The effects of nutritional deficiencies on the maroon-like maternal effect in Drosophila ... Phenocopies of the ma-l and ry mutants of Drosophila ...Missing: boron | Show results with:boron
[22]
Leaping lopsided - American Association for Anatomy
Injury to the limb buds of anuran tadpoles may, nonetheless, play an important role in limb malformation of free-living amphibians. As dis- cussed below, ...Missing: phenocopy | Show results with:phenocopy
[23]
A Quantitative Study of Phenocopy Production with ... - jstor
The term phenocopy was introduced by Goldschmidt (1935) to refer to produced by some experimental procedure, whose appearance duplicates or the phenotype of ...Missing: original | Show results with:original
[24]
Thresholds of Genotoxic and Non-Genotoxic Carcinogens - PMC
In contrast, non-genotoxic carcinogens, which induce cancer through mechanisms other than mutations, such as hormonal effects, cytotoxicity, cell proliferation ...
[25]
The Evolutionary Genetics of Canalization
In the broadest sense, genetic canalization refers to the robustness against both heritable genetic as well as epigenetic perturbations (Sollars et al. 2003).Abstract · THE PHENOMENON OF... · GENETIC AND... · THE MOLECULAR...<|control11|><|separator|>
[26]
https://pmc.ncbi.nlm.nih.gov/articles/PMC6195886/
[27]
https://www.journals.uchicago.edu/doi/10.1086/432265
[28]
Genetic assimilation, robustness and plasticity are key processes in ...
Plasticity and robustness both degrade the correlation between genetic variation and phenotypic variation. In robust systems mutations can accumulate on a ...
[29]
None
Nothing is retrieved...<|separator|>
[30]
The genetic background of chemically induced phenocopies in ...
The genetic background of chemically induced phenocopies in Drosophila. ... Authors. R B GOLDSCHMIDT, L K PITERNICK. PMID: 13481293; DOI: 10.1002/jez ...Missing: ether vapor curly wing
[31]
Developmental effects of exposing Drosophila embryos to ether ...
Drosophila embryos at precise developmental stages were exposed to ether vapour. The defects in the resulting embryos and adults were observed.Missing: curly | Show results with:curly
[32]
Genomic architecture of a genetically assimilated seasonal color ...
Nov 6, 2020 · We assimilated a seasonal wing color phenotype in a naturally plastic population of butterflies (Junonia coenia) and characterized three responsible genes.
[33]
The puzzle of locust density-dependent phase polyphenism
Locust density-dependent phase polyphenism is environmentally induced plasticity where crowding leads to the gregarious phase, and isolation leads to the ...Missing: phenocopy | Show results with:phenocopy
[34]
Comparative analysis of phenotypic plasticity sheds light on ... - Nature
Jun 7, 2021 · Locust phase polyphenism is one of nature's most striking examples of coordinated alternative phenotypes involving a myriad of density-dependent ...Missing: phenocopy | Show results with:phenocopy
[35]
Experimental evolution with Drosophila
Evolutionary biologists often use Drosophila as a model organism in experiments that test theories about the evolution of traits related to fitness.
[36]
Heat shock induced phenocopies of dominant mutants of ... - PubMed
Heat shock of 37 degrees C applied to Drosophila embryos at blastoderm stage induces phenocopies of some dominant mutants of the bithorax complex.
[37]
The Importance of Down Syndrome Phenocopies in the Newborns ...
As more the critical role of phenocopy emerges, the more the initial difficulty in detecting gene-gene interactions is amplified. Neglecting the possible ...
[38]
Genetic Defects in Thyroid Hormone Supply - Endotext - NCBI - NIH
Jan 12, 2018 · Congenital central hypothyroidism (CCH) is a rare disease in which thyroid hormone deficiency ... congenital hypothyroidism: defects in iodine ...
[39]
Linking environmental carcinogen exposure to TP53 mutations in ...
Sep 15, 2010 · Somatic mutations in TP53 have been found in approximately 50% of human cancers [5], and rare TP53 germline mutations (e.g. Li–Fraumeni syndrome) ...Missing: phenocopy | Show results with:phenocopy
[40]
Li-Fraumeni syndrome - Genetics - MedlinePlus
The cancers most often associated with Li-Fraumeni syndrome include breast cancer ... Fraumeni syndrome and Li-Fraumeni-like syndrome do not have TP53 mutations.Missing: carcinogens asbestos
[41]
Congenital Hypothyroidism - Medscape Reference
May 2, 2023 · Such areas were discovered to be low in iodine, and the cause of endemic cretinism was determined to be iodine deficiency.Missing: phenocopy | Show results with:phenocopy
[42]
The Iodine Deficiency Disorders - Endotext - NCBI Bookshelf
Feb 6, 2018 · Goiter was evident from 70 days in the iodine-deficient fetuses and thyroid histology revealed hyperplasia from 56 days gestation, associated ...Missing: phenocopy | Show results with:phenocopy
[43]
Genetic Assimilation of the Bithorax Phenotype - jstor
Drosophila melanogaster, using a heat shock applied to the pupa as the en- vironmental stimulus, and a crossveinless phenotype as the modification for which.
[44]
Control of Canalization and Evolvability by Hsp90 | PLOS One
Current models of canalization suggest that genetic buffering occurs as a by-product of environmental canalization, which should evolve under stronger and more ...<|separator|>
[45]
Polyphenism in Insects - ScienceDirect.com
Sep 27, 2011 · Polyphenism is the phenomenon where two or more distinct phenotypes are produced by the same genotype.Missing: phenocopy | Show results with:phenocopy
[46]
Resource‐based trade‐offs and the adaptive significance of ...
May 1, 2024 · Seasonal polyphenism in wing-melanin pattern and thermoregulatory adaptation in Pieris butterflies. The American Naturalist, 137(6), 816–830 ...Missing: phenocopy | Show results with:phenocopy
[47]
insights from epigenetic studies on natural populations - PMC
Feb 9, 2022 · Epigenetic mechanisms such as DNA methylation, histone modifications and non-coding RNAs are increasingly targeted in studies of natural populations.
[48]
Epigenetic Diversity and the Evolutionary Potential of Wild Populations
Oct 21, 2024 · A compilation of original research articles, reviews and opinions on the topic of epigenetics in wild populations.