CROSS FERTILIZATION IN PEAS UNDER DIFFERENT ECOLOGICAL CONDITIONS (II)

PNL Volume 17 1985 RESEARCH REPORTS 43

Loennig, W. E. Institute of Genetics

University of Bonn, Federal Republic of Germany

The work on natural cross fertilization in peas, studied by growing

control lines with green cotyledons among a great majority of plants

with yellow cotyledons (1,2), has been extended. WL 6040 was tested

again in 1984 in two ecologically different locations (Tables 1 and 2).

Table 1. Percent of cross fertilizations on Location I (WL 6040) ._

For location I the percentage of contaminated plants was about 10%

higher in 1984 than in 1983 (cf. PNL 16, p. 38) and for contaminated

seeds the difference was a bit more than a half percent above the value

of 1983. The values for location II were, however, very similar in the

two years (% of plants with cross fertilizations 1983: 30.4 and 1984:

29.87; % of yellow seeds 1983: 1.92 and 1984: 1.73).

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1985

RESEARCH REPORTS

PNL Volume 17 1985

RESEARCH REPORTS 45

Since Location II seems to have a richer insect fauna than Location

I, the higher percentage of contaminated plants found at Location I this

year was quite unexpected. Since no insecticide was sprayed on Location

II in 1984, this perhaps should have allowed a further increase in the

percentages of contaminated plants and seeds. It did not. Yet, because

the field was not sprayed, seed production was greatly reduced as a re-

sult of a high incidence of disease, particularly viral disease. This

explains the difference in the average seed production per plant between

the two fields (46.6 seeds per plant on Location I vs. 28.2 seeds per

plant on Location II).

Cross fertilization rates were also determined using WL 145 (long,

late, non-fasciated, green cotyledons). Table 3 shows the results for

Location I and Table 4 for Location II.

Usually 20 seeds were sown for each control group in both fields,

so the loss of plants was especially high in this line. The difference

between the average seed production per plant (45.8 seeds per plant on

Location I and 38.9 on Location II) was not as great as in the case of

WL 6040. The percentage of contaminated plants and seeds was greater in

Location II than Location I but the high values on Location II were

mainly due to the surprisingly high rates of cross fertilizations of

control groups 9 and 10 and for which there is no satisfactory expla-

nation. Having watched (and filmed) the different kinds of bumble bees

and a solitary bee species for many hours, I noted that these bees do

not seem to have the refined information systems that the honey bee has

for communicating the most productive parts of a field. Moreover,

bumble bee behavior is often rather erratic: leaving a red pea flower,

turning to different plant species of the meadow nearby, returning to

the pea field, flying from white to red flowers and vice versa, some-

times crossing the entire field and beginning its activity anew at the

most distant part of the field, etc.

Besides the two lines mentioned, WL 118 (medium height, as early as

DGV NF 15-1, non-fasciated, green cotyledons) also was investigated.

The control group, consisting of 36 plants, had two contaminated plants

(=5.6%) and produced 1682 seeds, two of which had yellow cotyledons

(=0.12%).

Moreover, a few recombinants were selected, resulting from cross

fertilizations between WL 6040 and probably DGV. They were in most res-

pects similar to DGV (height, non-fasciation, flowering and ripening

times, etc.) except, of course, for the green cotyledons (Table 5).

PNL Volume 17 1985

RESEARCH REPORTS

The final group investigated derived from a cross fertilization

between WL 6040 and probably again DGV, having green cotyledons but

which was still normally segregating in fasciated and non-fasciated

plants. Of the six non-fasciated plants, four were contaminated; all

six plants together produced 214 seeds, 14 of which had yellow cotyle-

dons. All four fasciated plants were contaminated; the four plants to-

gether produced 131 seeds, nine of which had yellow cotyledons (6.5 and

6.9% respectively for the non-fasciated and fasciated plants).

To make sure again that no mistakes had been made in determining

the cross fertilizations, 21 F2 families were studied (566 plants).

Since the M2 of R 650 A (3) contained several plants with the dominant

alleles Fa and/or Af (some of them with anthocyanin pigmentation) and

since we had several other similar cases among another M2, such plants

were chosen to determine whether any seeds of other lines might have

been mixed up with the M₂ seeds. All 21 families segregated. Among the

anthocyanin-producing plants we were able to ascertain the pollen source

as P. arvense from the color of the seed coats. These also segregated

for cotyledon color.

The real values for the cross fertilizations were in fact generally

slightly higher than given in the tables because doubtful cases were

systematically eliminated. On investigating such doubtful cases, we

found that some of them had really been the products of cross fertiliza-

tions.

Since the initiation of this study we have found at least:

969 plants with green cotyledons

620 plants for segregations

858 plants - M2 of R 650 A (plus other M₂'s not evaluated for

2447 this problem.

Moreover, at least 37,474 seeds have been investigated (segregations for

yellow and green seeds not included).

1. Loennig, W. E. 1983. PNL 15:40.

2. Loennig, W. E. 1984. PNL 16:38-40.

3. Loennig, W. E. 1984. PNL 16:42.