Amy Robach and T.J. Holmes, who were previously morning anchors for ‘GMA3’ before leaving ABC last year, have been spotted together publicly multiple times. However, their recent appearance at iHeartRadio’s Jingle Ball 2023 marked their first official public event as a couple. The couple looked happy and couldn’t hide their joy as they posed for pictures and faced the press with beaming smiles.
Amy Robach and T.J. Holmes made their first public appearance as a couple at iHeartRadio’s Jingle Ball 2023. This event not only confirmed their relationship but also marked a new joint venture as they prepare to launch their podcast, ‘Amy & T.J.’
During the event, not only did they embrace on the red carpet, but they also shared a kiss, making it clear that they are no longer hiding their relationship. Despite their relationship being well-known, this public display of affection confirmed their status as a couple.
Before attending the event, T.J. even hinted at their presence by posting a picture on his Instagram Story. The photo showed Amy in a car as she snapped a selfie, indicating that they were together and in town for the event.
It is worth noting that their attendance at the iHeart event was not just for show. They have a new podcast titled ‘Amy & T.J.’ set to launch next week, and they are encouraging people to listen to it on iHeart Radio.
This joint venture marks their first project together since leaving ABC. However, they have been inseparable since their departure and have been spotted enjoying vacations together as a couple. With the launch of their podcast, audiences can expect to see them back in action, discussing topics beyond their romantic relationship.
In conclusion, Amy Robach and T.J. Holmes showcased their love and unity during their first public event as a couple. Their new podcast signifies a step forward in their professional partnership, beyond their previous roles as morning anchors.
Stay tuned for more updates and content featuring Amy and T.J. as they continue to captivate audiences with their dynamic presence.