Biophysics Tools and Techniques for the Physics of Life (Mark C. Leake) (1)

392 Questions

takes a time t, and explain why this results in a peaked distribution to the experi

mentally measured wait time distribution for the ~30°–40° step.

8.18 The probability P that a virus at a distance d away from the center of a spherical cell of

radius r will touch the cell membrane can be approximated by a simple diffusion-to-

capture model that predicts P ≈ r/d.

By assuming a Poisson distribution to the occurrence of this touching event,

show that the mean number of touches of a virus undergoes oscillating between

the membrane and its release point before diffusing away completely is (r/2d 2)

(2d–r).

If a cell extracted from a tissue sample infected with the virus resembles an

oblate ellipsoid of major axis of 10 μm and minor axis of 5 μm with a measured

mean number of membrane touches of 4.1 ± 3.0 (±standard deviation) of a given

virus measured using single-particle tracking from single-molecule fluorescence

imaging, estimate how many cells there are in a tissue sample of volume 1 mL.

If the effective Brownian diffusion coefficient of a virus is 7.5 μm² s⁻¹, and the

incubation period (the time between initial viral infection and subsequent release

of fresh viruses from an infected cell) is 1–3 days, estimate the time taken to

infect all cells in the tissue sample, stating any assumptions that you make.

8.19 For 1D diffusion of a single-membrane protein complex, the drag force F is related to

the speed v by F = γv where γ is frictional drag coefficient, and after a time t, the mean

square displacement is given by 2Dt where D is the diffusion coefficient.

Show that if all the kinetic energy of the diffusing complex is dissipated in moving

around the surrounding lipid fluid, then D if given by the Stokes–Einstein rela

tion D = kBT/γ.

For diffusion of a particular protein complex, two models were considered for the

conformation of protein subunits, either a tightly packed cylinder in the mem

brane in which all subunits pack together to generate a roughly uniform circular

cross-section perpendicular to the lipid membrane itself or a cylindrical shell

model having a greater radius for the same number of subunits, in which the

subunits form a ring cross-section leaving a central pore. Using stepwise photo

bleaching of YFP-tagged protein complexes in combination with single-particle

tracking, the mean values of D were observed to vary as ~1/N where N was

the estimated number of protein subunits per complex. Show with reasoning

whether this supports a tightly packed or a cylindrical shell model for the com

plex. (Hint: use the equipartition theorem and assume that the sole source of the

complex’s kinetic energy is thermal.)

8.20 In a photobleaching experiment to measure the protein stoichiometry of a molecular

complex, in which all proteins in the complex were labeled by a fluorescent dye, by

counting the number of photobleach steps present, a preliminary estimate using a

Chung–Kennedy filter with window width of 15 data points suggested a stoichiom

etry of four protein molecules per complex, while subsequent analysis of the same

data using a window width of eight data points suggest a stoichiometry of six protein

molecules, while further analyses with window widths in the range three to seven

datapoints suggested a stoichiometry of ~12 molecules while using a window width

of two data points or using no Chung–Kennedy filter but just the pairwise difference

of single consecutive data points suggested stoichiometries of ~15 and ~19, respect

ively. What’s going on?

REFERENCES

KEY REFERENCE

Berg, H.C. (1983). Random Walks in Biology. Princeton University Press, Princeton, NJ.