John Val CV

Curriculum Vitae John Val

Education:

• High school (V.W.O) 1973-1980.
  

  	Program	(grade: scale 0-10)
  	Biology	9
  	Dutch	6
  	English	7
  	Mathematics I	9
  	Mathematics II	9
  	Physics	7
  	Chemistry	9

• University (Mathematical Biology, Leiden University) 1980-1987. grade 8.5
• Phd. mathematical biology (Leiden University) 1988-1992.
• First degree in teaching mathemathics (ICLON Leiden University) 2003-2005.

Jobs:

Specification qualities

• General:
  • Analytical and problem solving mind setting
  • Flexible
  • Eager to learn and explain
  • Perfectionist
• Courses:
  • Analysis
  • Algebra
  • Linear Algebra
  • Ordinary and partial- differential equations
  • Markov processes
  • Basics of probability theory
  • Discrete mathematics
  • Introduction to software engineering
  • Biokinetics (thermodynamics within biotechnology).
• Self study on books:
  • Introduction to the theory of statistics. Mood,Graybill and Boes.
  • Theoretical Statistics. Cox & Hinkley
  • Theory of Population Genetics and Evolutionary Ecology. Roughgarden.
  • Design Patterns. Gamma, Helm, Johnson & Vlissides.
  • Introduction to Quantitative Genetics. Falconer.
  • Building with photo voltaics. Novem.
• Teaching:
  • Assistantships:
    • Biomathematics ( 9 months, 4 hrs/week)
    • Introduction statistical analysis for biologists ( 3 months, 4 hrs/week)
    • Methods and techniques in biological sciences (1 month, 4 hrs/week)
  • Courses:
    • Teaching in a course on bioinformatics ( 6 weeks, full time)
    • Full organization and teaching of a course in A.P.L. (A Programming Language,) ( 3months, 4 hrs/week)
    • Organization and teaching of a course in plant physiology. ( 6 weeks, full time)
  • High school:
    • Mathematics: grade 1,2,4,5,6 vwo and 4,5 havo (4 years)
    • Biology: grade 5,6 V.W.O. ( 1 year 9 hrs/week )
    • ITC: grade 5,6 V.W.O.and 4,5 havo ( 3 years )
  • Other:
    • Skating instructor and coach. ( 8 years )
• Technical experience:
  • Pecoma: Transfer of database package from mainframe APL to PC- STSC APL.
  • Randstad: Lotus 123 macro's.
  • Phd. research: Hard- and Software (C/C++) developed for:
    1. Real-time control of fermentation vessels including monitoring (see 3) and sampling with user interface. (project leader)
    2. Data transfer from balance to PC. (project leader)
    3. Analogue-Digital conversion of the output of monitoring devices. (project leader)
    4. Solving differential equations and (graphical interactive) fitting of those to time series of experimental data. (project leader)
    5. Filtering the experimental data obtained with 3. (project leader)
  • West Consultancy:
    1. A variety of JAVA applets and applications for Client-Server and hardware communication protocols tools. (e.g. Albert Heijn
    2. Setup of WWW servers (mainly Netscape servers) at UNIX and Windows NT systems.
    3. Perl and JavaScript tools for Client-Server applications via WWW servers.
    4. Project leader in many of the projects performed for our clients.
  • Statistics Netherlands:
    1. Main client server application for exposing the data of Statistics Netherlands on the internet.
    2. COM applications for the MS-Windows 32 platform.
    3. Development of a pipeline process for the core business of Statistics Netherlands.
  • Rijnlands Lyceum:
    1. Math game under construction with assistance and levels up to first year VWO.
    2. algabric test environment under construction with assistance and error tracking.
  • Other:
    1. All kinds of specific software (C/C++, APL, Mathematica) for numerical analysis (e.g. root finding, genetic algorithms, cellular automata, solving partial differential equations) on DOS, Windows and Unix platforms. (project leader in all cases)
    2. Maintenance of DOS, Windows and Unix (IRIX en Linux) platforms and simple networking between those.
    3. Use of Excel, MS-Word, LATEX, Wordperfect, Emacs, Statgraphics and much more.
    4. WWW-Server installation, maintenance and site development
    5. Client sever applications (JAVA/PHP/ASP/MYSQL/ODBC)
• Management
  • Chairman of the Leiden Club for Biologists
  • Executive member of the Leiden Speedskating Club, organizing the yearly triathlon.
  • Organisation of anual climbing trip for families in spring.

Hobbies

• Speed skating
• construction
• rock climbing
• biking
• hiking
• theater
• music.

Scientific projects:

1. Optimal and evolutionary stable germination- and dispersal strategies in random fluctuating environments.

   A stochastic difference equation was build to represent a metapopulation of annual plants suffering from a variable environment. The annual plants were allowed to spread their risk by either an escape in space (dispersal) or in time (delayed germination). Optimal germination and dispersal fractions were calculated for different levels of environmental fluctuations, different size and connectivity in the metapopulation, and for different values of mortality during dispersal and delaying germination. In Klinkhamer et. al. (1987) we focused on the case of r- selection (maximum growth rate). Later research also focused on density dependent selection (ESS) (unpublished so far). The parameter subset providing an optimum where both dispersal and delayed germination are present is much larger in the case of K-selection than in the case of r-selection.

2. Cell proliferation in batch cultures, a theoretical approach

   Proliferation of plant cells in liquid medium is influenced by the composition of that medium. A stochastic model for cell division has been approximated with a deterministic model in which a cell is subdivided in compartments having different biochemical properties. Population dynamics is modeled with a set of partial differential equations (Metz & Diekmann 1986). Using Linear Chain Trickery, this set is transformed to a set of delay differential equations. Monte-Carlo studies and non-linear curve fitting gave rise to a close match with experimental data. See http://www.johnval.nl/biology/thesis for the online publication.

3. Respiration in intact plant cells: Modeling the control of respiration

   Plant cells are able to reduce oxygen via two main pathways. Besides the common eucaryotic cytochrome respiratory pathway, plant cells have the possibility to reduce oxygen in a cyanide resistant pathway. Processes involved in respiration are: the energy requirements of the cell (mol ATP per unit time), respiration itself, and sugar consumption. A model is put forward including both pathways and the two other processes. In the literature there are two negative feedback processes proposed. One in which ATP inhibits the respiratory chain directly, and one in which ATP inhibits glycolysis, i.e the influx of reducing equivalents to the respiratory pathways. We examined which of these regulatory mechanisms could be in favor, by fitting the highly non-linear equations to the data. Although regulation via glycolysis has certain advantages, our experimental data are not able to give evidence for one or the other regulatory mechanism. See http://www.johnval.nl/biology/thesis for the online publication.

4. Metapopulation dynamics

   Individuals live in a intrinsic non-homogeneous environment. In this project a landscape is divided in patches, suitable for habitation by some species, and non-habitat, in which habitation by this species is impossible. Models developed for this system are compared to models in which the spatial component is less or more pronounced.

   An individual based deterministic model is evaluated for species for which the local density can be high and which individuals have a high probability for dispersal. The landscape exist out of an infinite number of patches. Next to common individual mortality, disasters occur which wipe out the total or a part of the local population. The resulting models are non-linear partial differential equations. It appears that non-spatial models are as good in predicting metapopulation existence. However, those models still have a need for understanding of process at the spatial and individual level, since the parameters in the simple models are combinations of parameters from the spatial model. The simple models are less suitable for determination of the equilibria and dynamics of the spatial system, but still can be of use for examining the boundaries of population behavior. These results are supplemented with results form models with a landscape consisting of a finite number of patches. Metapopulation extinction happens with probability 1, but mean lifetime of a population can tend to infinity. Monte-Carlo simulations give rise to distributions for time till extinction of the metapopulation.

   A paper on this metapopulation model can be found at http://www.johnval.nl/biology/mpop

5. Modeling the cell division cycle and population dynamics of the yeast Sachromyces Cerevisiae ( budding yeast )

   In recent years an understanding of the molecular mechanisms for the budding yeast cell cycle has rapidly increased. There are still many questions to be resolve experimentally but we started modeling of the cell cycle to bring about an understanding of the connection between the various molecular mechanisms, and more over an understanding of the coupling form the chemical model to the observed population behavior of yeast cultures. We try to build models which are as simple as possible, and still will be able to explain many of the kinetics of mutant cell lines.

   A description of the model for the population dynamics of budding yeast can be found at http://www.johnval.nl/biology/sizedist

6. Development of a client-server application for the numerical bifurcation analysis of dynamical systems.

   Mathematical modeling of dynamical systems is becoming increasingly important. In many case mere numerical simulation of models reveals only a minor set of all possible behavior of the dynamical system. Numerical bifurcation analysis can reveal a larger set of all possible behavior for it helps determining parameter regions in which the dynamical system shows similar behavior. As a simple example it can determine stable and unstable regions of the dynamical system through the computation of a curve of equilibria of the system by changing one of the parameters of the system. During this computation it looks for changes in the sign of the real part of the dominant eigenvalue of the system at the computed equilibrium. This change in sign predicts the loss or gain of a stable equilibrium. The mathematical theory is currently capable of detecting many possible behavioral changes, such as appearance, branching and stability of equilibria and appearance and stability of (multi periodic) cycles. However there is a lack of easy accessible software tools for the less mathematical experienced researcher. In this project a software application is developed with the aim of filling this gap. The software tool will also be helpful for teaching purposes.

Publications:

• Klinkhamer,P.G.L.,de Jong, T.J., Metz, J.A.J., and Val, J. 1987. Life history tactics of annual organisms: The joint effects of dispersal and germination. Theor. pop. biol. 32, 127-156.
• De Gunst, M.C.M., Harkes, P.A.A., Val, J., Zwet, W.R., and Libbenga, K.R. 1990. Modeling the growth of a batch culture of plant cells: A corpuscular approach. Enzyme Microb. Technol., 12,61-71
• Blom, T.J.M., T.B. van Vliet, J. Schripsema, J. Val, F.van Iren, R. Verpoorte, K.R. Libbenga. 1991. Uptake and accumulation of the alkaloids Quinine and Cinchonamine in cultured cells of Cinchona robusta and Catharanthus roseus. J.Plant Physiol. 138,436-442.
• Kreiss, W., Fulzele, D.P., Hoelz, H., Val, J., Reinhard, E. 1992. Production of cardenolides by Digitalis cell cultures-models and process options. In: Plant tissue Culture and Gene Manipulation for Breeding and Formation of Phytichemicals (K. Oono et al. eds.): 335-354.
• Nicoloso, F.T., Val, J. Keur, M. van der, Iren, F. van, Kijne, J.W. (1994) Flow-cytometric cell counting and DNA estimation for the study of plant cell population dynamics. Plant Cell, Tissue and Organ Culture 39,251-259.
• Tyson, J.J., Novak, B., Chen, K.C., and Val, J. (1995). Checkpoints in the cell cycle from a modeler's perspective. In: Progress in Cell Cycle Research, ed. L. Meijer, S. Guidet, and H.Y.L. Tung, New York: Plenum Press, 1-8.
• Val, J., Hoefnagel, M., Koens, K., Nicoloso F., van Iren, F., Heijnen, J.J., Libbenga, K.R., (submitted). A Cellular Model Relating the Kinetics of Biomass and Cell Proliferation in Batch Fermentation of Nicotiana tabacum, including a validation of structured kinetic models and a description of the switch from Primary to Secondary Metabolism.
• Val, J., Metz, J.A.J. (to appear in the proceedings of the 3 'th international conference on population dynamics). Infinite Exact Finite Dimensional Representations of Models for Physiologically Structured Populations: the Concept of Weakly Linear Chain Trickery
• Val, J.,Villa, F.,Lika, K.,Boe, C. 1997.Nonlinear Models for Structured Populations; Dynamic consequences of stage-structure and discrete sampling. In: Structured-population models in marine, terrestrial, and freshwater systems (Tuljapurkar, S. and Caswell, H, eds),587-614.
• Val, J., Verboom, J., Metz, J.A.J. (submitted). A Deterministic Size-Structured Metapopulation model.
• Val, J., Tyson, J.J. (accepted for publication in the proceedings of the 4'th international conference on mathematical population dynamics ) A purely deterministic model for the population dynamics of budding yeast.
• Chen K.C., Csikasz-Nagy A., Gyorffy B., Val J.,Novak B., Tyson J.J. 2000. Kinetic Analysis of a Molecular Model of the Budding Yeast Cell Cycle. MBC 11, Issue 1, 369-391.