• Korean journal of applied entomology
• /
• v.41 no.4
• /
• pp.247-253
• /
• 2002

Based on accumulated data during 1977-2001, seasonal fluctuations of migrated aphids at Daegwallyeong highlands were analyzed. In addition, rates of PLRV transmission by migrated aphids were investigated by inoculation on indicator plant, Physazis floridana, and ELISA in 2000-2001, and the change of PLRV transmission rates by aphids was compared with that of 1989-1991. The average migrated aphid population densities in 1976-1980, 1991-1995, and 1996-2000 were 575.2, 2959.4 and 2281.6, respectively, showing gradual increase in recent years. The average peak time of aphid migration was from early to mid June during 1977-2001, showing any significant differences over the years. The dominant species, however, changed slowly; before mid 1980s M. persicae flied dominantly, but after mid 1980s Aphis gossypii did. Hahm et al. (1991) reported that PLRV transmission rate of migrated aphids during 1989-1991 was 6.7-10.0%. In 2000-2001, however, migrated aphids at Daegwallyeong highland showed 10.1-11.0%. Although present PLRV transmission rate was slightly higher than that of 10 years ago, taking increased population densities and diversity of migrated aphids into account, there was no significant change of PLRV transmission rate over the years.

• Korean journal of applied entomology
• /
• v.57 no.4
• /
• pp.415-423
• /
• 2018

Aphid is a typical vector that transfers various kinds of viruses to potatoes. Therefore, it is very important to control aphids moving into potato fields. We investigated the seasonal movement pattern of aphids and its virus transmission rates mainly in the three seed potato production regions at highland in Gangwon-do, Korea. In addition, we identified the aphid species with over-wintering eggs collected from barks or twigs of total 57 tree species around potato fields in winter season. The peak time of summer and winter migration of aphid was at the mid-June and the early October, respectively. A 2.8% of total aphid trapped in yellow water-pan trap was turned out PLRV-borne, and the virus transmission rate was 15.4% by Myzus persicae and 9.1% by Macrosiphum euphorbiae. PLRV-borne aphids started to flow in from the late May, and virus transmission rate of aphid trapped in mid-June was the highest with 10.4%. Totally 14 species of aphid eggs wintered in the 17 species of trees including Acer pictum subsp. mono and Acer pseudosieboldianum at the 11 sites. In particular, because it is not certain that Betula platyphylla var. japonica and Yamatocallis hirayamae do transmit potato virus, but they over-wintered in host plants distributed over a wide area, further research on transmission ability is necessary.

• The Plant Pathology Journal
• /
• v.33 no.5
• /
• pp.522-527
• /
• 2017

We determined the effects of atmospheric temperature ($10-30{\pm}2^{\circ}C$ in $5^{\circ}C$ increments) and carbon dioxide ($CO_2$) levels ($400{\pm}50ppm$, $540{\pm}50ppm$, and $940{\pm}50ppm$) on the infection of Solanum tuberosum cv. Chubaek by Potato leafroll virus (PLRV). Below $CO_2$ levels of $400{\pm}50ppm$, the PLRV infection rate and RNA content in plant tissues increased as the temperature increased to $20{\pm}2^{\circ}C$, but declined at higher temperatures. At high $CO_2$ levels ($940{\pm}50ppm$), more plants were infected by PLRV at $30{\pm}2^{\circ}C$ than at 20 or $25{\pm}2^{\circ}C$, whereas PLRV RNA content was unchanged in the $20-30{\pm}2^{\circ}C$ temperature range. The effects of atmospheric $CO_2$ concentration on the acquisition of PLRV by Myzus persicae and accumulation of PLRV RNA in plant tissues were investigated using a growth chamber at $20{\pm}2^{\circ}C$. The M. persicae PLRV RNA content slightly increased at elevated $CO_2$ levels ($940{\pm}50ppm$), but this increase was not statistically significant. Transmission rates of PLRV by Physalis floridana increased as $CO_2$ concentration increased. More PLRV RNA accumulated in potato plants maintained at 540 or $940{\pm}50ppm$ $CO_2$, than in plants maintained at $400{\pm}50ppm$. This is the first evidence of greater PLRV RNA accumulation and larger numbers of S. tuberosum plants infected by PLRV under conditions of combined high $CO_2$ levels ($940{\pm}50ppm$) and high temperature ($30{\pm}2^{\circ}C$).