Temperature effects on spectral properties of the two types
of rod photoreceptors in toad retina, “red” and
“green” rods, were studied in the range
0–38°C. Absorbance spectra of the visual pigments
were recorded by single-cell microspectrophotometry (MSP) and
spectral sensitivities of red rods were measured by
electroretinogram (ERG) recording across the isolated retina.
The red-rod visual pigment is a usual rhodopsin
(λmax = 503.6 nm and 502.3 nm at room temperature
(21°C) in, respectively, Bufo marinus and Bufo
bufo), that of green rods (λmax = 432.6
nm in Bufo marinus) belongs to the “blue”
cone pigment family. In red rods, λmax depended
inversely and monotonically on temperature, shifting by −2.3
nm when temperature was raised from 0°C to 38°C. Green-rod
λmax showed no measurable dependence on
temperature. In red rods, warming caused a relative increase
of sensitivity in the long-wavelength range. This effect can
be used for estimating the energy needed for photoexcitation,
giving Ea = 44.3 ±
0.6 kcal/mol for Bufo marinus rhodopsin and 48.8
± 0.5 kcal/mol for Bufo bufo rhodopsin.
The values are significantly different (P < 0.001),
although the two rhodopsins have very similar absorption spectra
and thermal isomerization rates. Our recording techniques did not
allow measurement of the corresponding effect at long wavelengths
in green rods. Although spectral effects of temperature changes in
the physiological range are small and of little significance for
visual function, they reveal information about the energy states and
different spectral tuning mechanisms of the visual pigments.