Ronald J. Konopka (1947-2015) was an American geneticist who studied

chronobiology Chronobiology is a field of biology that examines timing processes, including periodic (cyclic) phenomena in living organisms, such as their adaptation to solar- and lunar-related rhythms. These cycles are known as biological rhythms. Chronob ...

. He made his most notable contribution to the field while working with ''

Drosophila ''Drosophila'' () is a genus of flies, belonging to the family Drosophilidae, whose members are often called "small fruit flies" or (less frequently) pomace flies, vinegar flies, or wine flies, a reference to the characteristic of many speci ...

'' in the lab of Seymour Benzer at the

California Institute of Technology The California Institute of Technology (branded as Caltech or CIT)The university itself only spells its short form as "Caltech"; the institution considers other spellings such a"Cal Tech" and "CalTech" incorrect. The institute is also occasional ...

. During this work, Konopka discovered the ''

period Period may refer to: Common uses * Era, a length or span of time * Full stop (or period), a punctuation mark Arts, entertainment, and media * Period (music), a concept in musical composition * Periodic sentence (or rhetorical period), a concept ...

'' (''per'') gene, which controls the period of

circadian rhythms A circadian rhythm (), or circadian cycle, is a natural, internal process that regulates the sleep–wake cycle and repeats roughly every 24 hours. It can refer to any process that originates within an organism (i.e., endogenous) and responds to ...

Academic career

Ron Konopka received his

Ph.D A Doctor of Philosophy (PhD, Ph.D., or DPhil; Latin: or ') is the most common degree at the highest academic level awarded following a course of study. PhDs are awarded for programs across the whole breadth of academic fields. Because it is ...

. in Biology from the California Institute of Technology in 1972. In 1975, following his discovery of the ''period'' mutants, Konopka was awarded a faculty position at the California Institute of Technology. While there, Konopka's colleagues were critical of his reluctance to publish his work on the ''period'' gene, and Konopka was denied

tenure Tenure is a category of academic appointment existing in some countries. A tenured post is an indefinite academic appointment that can be terminated only for cause or under extraordinary circumstances, such as financial exigency or program disco ...

. After his stay at Caltech, Konopka accepted a position at

Clarkson University Clarkson University is a private research university with its main campus in Potsdam, New York, and additional graduate program and research facilities in the New York Capital Region and Beacon, New York. It was founded in 1896 and has an enr ...

but was again denied tenure and subsequently exited the field of science. Konopka's career, interwoven with the work of his mentor, Seymour Benzer, and the other scientists working in Benzer's lab is narrated in ''

Time, Love, Memory ''Time, Love, Memory: A Great Biologist and His Quest for the Origins of Behavior'' is a book by American non-fiction writer Jonathan Weiner, published in 1999. The book is a biography of California Institute of Technology biologist Seymour Ben ...

'' by

Jonathan Weiner Jonathan Weiner (born November 26, 1953) is an American writer of non-fiction books based on his biological observations, focusing particularly on evolution in the Galápagos Islands, genetics, and the environment. His latest book is ''Long for ...

. Konopka's discovery and genetic analysis of ''period'' and several other circadian rhythm mutations became the basis of the research done by Drs. Jeffrey C. Hall, Michael Rosbash, and Michael W. Young, who were awarded the 2017 Nobel Prize in Physiology or Medicine.

Research

''Period'' mutants

Discovery of ''Period''

As a graduate student in Seymour Benzer's lab, Konopka sought to use Benzer's method of behavioral genetics to unravel the mysteries of the "master clock" that existed in every organism. He used ethyl methanesulfonate (EMS) to induce point mutations in the ''Drosophila melanogaster'' genome, and eventually isolated three mutants with abnormal rhythms in

eclosion A pupa ( la, pupa, "doll"; plural: ''pupae'') is the life stage of some insects undergoing transformation between immature and mature stages. Insects that go through a pupal stage are holometabolous: they go through four distinct stages in their ...

. He mapped the mutations to the same location on the far left of the

X chromosome The X chromosome is one of the two sex-determining chromosomes (allosomes) in many organisms, including mammals (the other is the Y chromosome), and is found in both males and females. It is a part of the XY sex-determination system and XO sex ...

, less than 1

centimorgan In genetics, a centimorgan (abbreviated cM) or map unit (m.u.) is a unit for measuring genetic linkage. It is defined as the distance between chromosome positions (also termed loci or markers) for which the expected average number of intervening ...

away from the ''white'' gene locus. These mutations were alternative alleles of a gene that Konopka subsequently named ''period''. While wild type flies have a circadian period around 24 hours, Konopka found the ''per⁰¹'' mutant was arrhythmic, the ''per^S'' mutant had a period of 19 hours, and the ''per^L'' had a period of 29 hours.

Neurobiology of ''per'' mutants

In 1979 and a 1980, Konopka and Dominic Orr tested whether mutations in ''per'' mutations affected the period of the entire circadian cycle or just a portion of it. By comparing the light responses of ''per^S'' eclosion rhythm to that of wild type flies, Konopka and Orr found that light pulses reset the mutant clock to a greater extent than the wild type clock (about 10 hours for ''per^S'' compared to 3 hours for wild type flies). They also observed that the while duration of the light-sensitive part of the day (subjective night) was found to be similar between ''per^S'' and wild type flies, the duration of the light-insensitive part of the cycle (subjective day) was 5 hours shorter in mutant flies than in wild type flies. They concluded that differences in period length between mutant and wild type flies could be accounted for by a shortening of the subjective day, or the active part of the circadian cycle, in ''per^S'' mutants. From this, Konopka concluded that separate molecular processes correspond to the subjective night and subjective day and that the ''per^S'' allele acts by shortening the subjective day while leaving the subjective night unchanged. Based on these findings, Konopka and Orr constructed a model for the action of the ''per'' gene. The oscillation is interpreted in terms of a membrane gradient that is established during the subjective day and dissipates during the subjective night. The model predicts that the ''per'' gene product is active during the subjective day and functions like a pump to establish the gradient. Once a high threshold is reached, the pump shuts off and light-sensitive channels open to dissipate the gradient. A light pulse during the subjective night closes the channels and starts the pump; the value of the gradient when the channels close is the same as the value when the pump starts, and thus a reset in the cycle is produced and an oscillation results. This model has been replaced with a transcription translation negative feedback model involving ''timeless'', ''clock'', and ''cycle''. Also in 1980, Konopka and Steven Wells reported an abnormality in the morphology of a neurosecretory cell group associated with the arrhythmic ''per⁰¹'' mutation and with 2 arrhythmic mutants of another fly strain, '' Drosophila pseudoobscura''. This cell group normally consists of four clustered cells in either side of the brain, roughly halfway between the top and bottom edge, in the posterior area of the brain. Cells in this cluster are occasionally located abnormally near the top edge, rather than the middle, of the brain at a rate of about 17% of cells in wild-type ''D. melanogaster''. The ''per⁰¹'' mutation significantly increases the percentage of abnormally located cells to about 40%. In two aperiodic strains of ''D. pseudoobscura'', the percentages of abnormally located cells are likewise significantly increased over those in the wild type. Konopka inferred from the results that neurosecretory cells may be part of the ''Drosophila'' circadian system and that ''per'' gene product may influence the development of these cells.

Pacemaker signalling

In 1979 Konopka worked with Alfred Handler to discover the nature behind pacemaker signalling by transplanting brains of donor flies into abdomens of arrhythmic host flies. They found that circadian rhythms in host flies were restored with the period of the donor; for example, short period (''per^S'') adult brains implanted into the abdomens of arrhythmic (''per⁰¹'') hosts could confer a short period rhythm on the activity of some hosts for at least 4 cycles. Since the transplanted brains were unable to create new neuronal connections to locomotor activity centers, Konopka and Handler concluded that pacemaker signalling for locomotion must be humoral and not neuronal.

Reciprocal behavior of ''per'' mutants

While at Clarkson College, Konopka continued his work with Orr and also collaborated with chronobiologist Colin Pittendrigh. During the collaboration, Konopka worked to understand behaviors of ''Drosophila'' ''per'' mutants beyond their abnormal period lengths. Konopka was primarily interested in how these mutants behaved in constant light or constant darkness and whether they conformed to the rules established by chronobiologist Jurgen Aschoff. In addition, Konopka also observed behavior of the flies under varying light intensities and over a range of temperatures. Konopka found that the ''per^S'' and ''per^L'' flies showed reciprocal behaviors under the experimental conditions. For example, ''per^S'' period shortened, while ''per^L'' period lengthened in response to decreasing temperature. Konopka hypothesized that these reciprocal behaviors were a manifestation of two coupled oscillators, a model proposed in 1976 by Pittendrigh and Daan.

Other circadian mutants

''Clock'' mutants

In 1990, Konopka collaborated with Mitchell S. Dushay and Jeffery C. Hall to further investigate the effects of the ''clock'' gene in ''D. melanogaster''. Konopka had noted in 1987 that the ''Clock'' (''Clk'') mutant, induced via chemical mutation, was a semidominant mutation that shortened the rhythm of locomotor activity in flies by around 1.5hr. Dushay, Konopka and Hall noted that ''Clk'' mutants had phase response curve that was shortened from 24hr to 22.5hr, and that the short period was also observable in the eclosion rhythm of the mutant flies. ''Clk'' was mapped close enough to the ''per⁰¹'' mutation such that it could be considered a ''per'' allele, but due to the presence normal courtship song rhythms in ''Clk'' males and the lack of coverage of its effects via duplications, Dushay and Konopka determined that ''Clock'' was a novel circadian mutation.

''Andante'' mutants

By working with Randall F. Smith and Dominic Orr of Caltech, Konopka discovered a new circadian mutant, named ''Andante'', in 1990. In contrast to ''Clock'', ''Andante'' lengthens the period of eclosion, and locomotor activity by 1.5–2 hours, and was also shown to lengthen the periods of other circadian mutants. ''Andante'' is a semi-dominant mutation, temperature compensated, and unaffected by the ''sine oculis'' mutation, which eliminates the outer visual system of flies. It was mapped to the 10E1-2 to 10F1 region of the ''D. melanogaster'' X chromosome, close to the ''miniature-dusky'' locus.

References

External links

2000 Brief Interview with Konopka on period gene
{{DEFAULTSORT:Konopka, Ron Living people American geneticists California Institute of Technology alumni California Institute of Technology faculty Clarkson University faculty Chronobiologists 1947 births